JP2004076370A - Excavation tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an excavation tool provided with a widening bit rotatably fitted to the tool body by shaft hole fitting and recyclably made without disposing of the widening bit or the tool body even if abrasion arises in the shaft or the inner/outer peripheral part of the hole to improve the economical efficiency. <P>SOLUTION: In the excavation tool in which a widening bit 4 rotatable around the center axis X deviated from the axial line O and positioned in the state that the outer diameter from the axial line O is widened, is attached to the outer periphery of the front end of the tool bodies 1, 7 rotated around the axial line O, the widening bit 4 is rotatably fitted to the tool bodies 1, 7 by fitting of the shaft 4B, 4C extending along the center axis X and holes 3G, 9D, and collars 10A, 10B are attached to at least one of the outer periphery of the shaft 4B and the inner periphery of the hole 9D. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
According to the present invention, a drill bit having a predetermined diameter is formed by attaching a diameter-enlarging bit to an outer periphery of a tip end portion of a tool body that is rotated around an axis, and positioning the enlarged diameter bit in an expanded state during excavation. Related to a drilling tool to be used.
[0002]
[Prior art]
As this type of excavating tool, a device (tool main body) that is rotated around an axis, and a shaft that extends in the center axis direction eccentric from the axis on the outer periphery of the tip portion, and is rotated around the center axis by fitting. A plurality of expanding bits that are mounted so as to be capable of being mounted.When the device is rotated around the axis during the excavation in the direction of rotation during the excavation, the expanding bit rotates around the respective central axis due to the excavation resistance. Then, when the device is rotated in the opposite direction to the rotation direction, the diameter-expanding bit is also different from the above-described position when the side surfaces contact each other to position the outer diameter from the axis. It is known that when the outer diameter is reduced by rotating in the opposite direction, the side surfaces are in contact with each other and the outer diameter is reduced. In addition, the inventors of the present invention disclose, for example, in Japanese Patent No. 3014349, a pilot bit is attached so as to protrude toward the distal end side on the axis of the distal end of a device that is rotated around an axis. A tool main body is constituted by the pilot bit, and a center axis also eccentric from the above-mentioned axis is provided between the front end of the device and the back surface of the main body of the pilot bit in the axial direction on the outer periphery of the front end of the tool main body. There has also been proposed one provided with a plurality of diameter-enlarging bits rotatable about the central axis by fitting a shaft hole extending in the direction.
[0003]
Such an excavating tool is inserted into a cylindrical casing in a state where the diameter-expanding bit is reduced, protrudes the diameter-expanding bit from the end of the casing, and is rotatable around the axis and toward the end. Can be advanced integrally with the casing. During excavation, the outer diameter of the diameter-expanding bit is larger than the outer diameter of the casing because the tool body receives the rotational force in the above-mentioned rotational direction and the impact force toward the tip end. When the casing is built into the drilled hole while forming a drilled hole, the casing is laid forward while forming a drilled hole, and the drilled hole is formed to a predetermined depth. By rotating the main body in the opposite direction, the diameter-enlarging bit is reduced in diameter, so that it can be pulled out from the hole while leaving the casing in the hole. In a drilling tool in which the pilot bit is provided in the tool main body, the pilot bit first forms a small-diameter hole, and then the subsequent enlarged bit expands the hole to form a drilling mode. The excavation by the pilot bit will excavate the ground where the earth and sand and rocks are apt to collapse, so that the excavation efficiency can be improved.
[0004]
[Problems to be solved by the invention]
By the way, in these excavating tools, as described above, the diameter-enlarging bit is attached to the tool main body so as to be rotatable around the central axis by fitting the shaft extending in the central axis direction and the hole, that is, normally, the expanding bit. By inserting a cylindrical shaft integrally provided with the diameter bit into a hole formed around the center axis on the device or pilot bit side of the tool body, the outer peripheral portion of the shaft is formed on the inner circumference of the hole. The diameter expansion bit is rotated while sliding on the portion, and the outer diameter thereof can be expanded or reduced. However, during the excavation with such a drilling tool, when the diameter of the diameter-expanding bit is repeatedly increased and decreased, and the outer peripheral portion of the shaft slides frequently along the inner peripheral portion of the hole, the outer peripheral portion of the shaft and the inner portion of the hole may be removed. It is inevitable that wear will occur on the peripheral part or on both sides, and as a result, there will be a gap between the two parts, causing the diameter-enlarging bit to rattle, making it impossible to perform stable excavation. The shaft may be broken due to the load or impact during excavation acting on the enlarged diameter bit. Therefore, if the abrasion occurs in the enlarged diameter bit due to the wear, the enlarged diameter bit having the worn shaft and hole, the tool body, or both of them must be discarded and replaced with a new one. There has been a problem that the tool life is shortened and it is extremely uneconomical.
[0005]
The present invention has been made under such a background, and in an excavating tool having an enlarged bit rotatably attached to a tool body by the above-described shaft hole fitting, the inside and outside of the shaft and the hole are provided. The first object of the present invention is to provide a drilling tool which can be reused without discarding a diameter expanding bit and a tool main body even if wear is generated on a peripheral portion, thereby improving economic efficiency. An object of the present invention is to provide a drilling tool capable of suppressing the occurrence of wear on the inner and outer peripheral portions of the shaft and the hole itself and preventing the rattling of the diameter-enlarging bit and breakage of the shaft.
[0006]
[Means for Solving the Problems]
In order to solve the above-described problems and first achieve the first object, the present invention is configured to be rotatable around a central axis eccentric from the axis on the outer periphery of the tip end portion of the tool body rotated about the axis. A drilling tool to which a diameter-enlarging bit positioned in a state where the outer diameter from the axis is expanded is attached, wherein the diameter-enlarging bit is fitted to the tool body by fitting a shaft extending along the central axis with a hole. It is rotatably mounted, and a collar is mounted on at least one of the outer peripheral portion of the shaft and the inner peripheral portion of the hole. Therefore, according to such a drilling tool, since the shaft and the hole are worn on the side on which the collar is attached in this manner, the worn-out collar is replaced by replacing the worn-out bit and the tool body without initially discarding the worn-out bit. And the stable excavation can be performed. In order to achieve the second object, the present invention is characterized in that the collar has a hardness higher than at least one of an outer peripheral portion of the shaft and an inner peripheral portion of the hole, that is, a tool main body. The wear of the collar is suppressed because the collar is harder than the inner periphery of the shaft and hole formed in the diameter-enlarged bit, and therefore, the gap between the shaft and the hole due to wear is prevented. It is possible to prevent rattling of the enlarged diameter bit and breakage of the shaft. Further, such a collar may be fixedly attached to at least one of the outer peripheral portion of the shaft and the inner peripheral portion of the hole by shrink fitting, cooling shrinking, press-fitting, etc. If the collar is removably attached to the collar, the collar can be easily and promptly restored to its original state even when the collar is replaced due to wear or damage.
[0007]
BEST MODE FOR CARRYING OUT THE INVENTION
1 to 10 show a first embodiment of the present invention. As shown in FIG. 1, the device 1 constituting the tool body in the present embodiment has a substantially multi-stage cylindrical shape having a front end 1A one step larger in diameter than a rear end 1B. By attaching a hammer (not shown) to 1B, during excavation, a rotating force is applied around the axis O in the direction indicated by the symbol T in the figure, and a striking force is applied to the tip side (the left side in FIG. 1) in the direction of the axis O.
[0008]
Further, as shown in more detail in FIG. 4, the distal end portion 1A has a multistage shape in which the rear end portion is slightly larger in diameter than the front end side, so that the outer periphery of the rear end portion is formed. A step portion 1C that is one step protruding toward the rear end side is formed. The outer diameter of the step portion 1C, that is, the maximum diameter of the device 1 is set to a size that can be inserted into the inner periphery of a cylindrical casing (not shown). On the other hand, the outer diameter of the distal end portion of the distal end portion 1A, which is closer to the distal end side than the step portion 1C, is fitted to the inner periphery of a cylindrical casing top (not shown), which is one step smaller than the inner diameter attached to the leading end of the casing. When the stepped portion 1C comes into contact with the rear end of the casing top, only the striking force is transmitted to the casing, and the casing moves forward so that the casing can be built in the hole. In addition, a step portion 1D which is one step protruding toward the rear end side is formed on the outermost portion at the tip end of the tip portion 1A, and is perpendicular to the axis O inside the step portion 1D. A flat tip surface 1E is formed, and the outer diameter of the tip surface 1E is made smaller by the step 1D than the outer diameter of the tip 1A on the tip side of the step 1C. I have.
[0009]
On the outer periphery of the distal end portion 1A of the device 1, a pair of dust discharging grooves 2A and 2B having a rectangular cross section and having a circumferential width and a radial depth substantially equal to the axis O are respectively provided. The pair of discharges are formed so as to extend from the step portion 1D to the rear end of the tip portion 1A in parallel with the axis O and to be adjacent to each other at intervals in the circumferential direction. A plurality of pairs (four pairs in the present embodiment) of grooves 2A and 2B are formed so as to be located at equal intervals in the circumferential direction. Furthermore, in the present embodiment, of the pair of scouring powder discharge grooves 2A, 2B, the discharge grooves 2A located on the rear side in the respective rotation direction T (clockwise in FIGS. 2 and 3). Are formed on the outer peripheral side of the distal end portion 1A of the device 1 so as to communicate with the distal end side of the device 1. Accordingly, in this embodiment, a plurality (four) of the concave portions 3 are formed at equal intervals in the circumferential direction. The Rukoto. The plurality of recesses 3 and the pair of discharge grooves 2A, 2B are formed so as to have the same shape at a rotational position of 90 ° around the axis O.
[0010]
The concave portion 3 is recessed toward the rear end side in the direction of the axis O from the distal end surface 1E at the forefront of the device 1 to a position beyond the step portion 1D, and radially within the distal end surface 1E. The rotation direction T of the discharge groove 2B paired with the discharge groove 2A in the circumferential direction so as to open from the position spaced from the axis O to the outer peripheral side beyond the stepped portion 1D and to the outer periphery of the distal end portion 1A. It is formed from the rear edge to the space between the discharge groove 2A and the next discharge groove 2B on the rear side in the rotation direction T. More specifically, as shown in FIG. 4 and FIG. A wall surface 3A facing the rotation direction T, a wall surface 3C facing the outer peripheral side smoothly connected to the wall surface 3A via a concave cylindrical wall surface 3B, and an outer surface intersecting the wall surface 3C at an obtuse angle. Wall surface 3D facing the rear side in the rotation direction T that is concavely bent 3E and a bottom surface 3F facing the distal end side. The bottom surface 3F is formed in a direction perpendicular to the axis O, and the wall surfaces 3A to 3E are formed so as to extend parallel to the axis O. . The bottom surface 3F is formed at a position where the step 1C on the rear end side of the front end portion 1A of the device 1 is slightly protruded from the front end of the casing top in a state where the step portion 1C is in contact with the rear end of the casing top as described above. Is done. The bottom surface 3F is formed with a hole 3G having a circular cross section with a constant inside diameter centered on the central axis X of the concave cylinder formed by the wall surface 3B, and the opening of the discharge grooves 2A, 2B to the bottom surface 3F. The inclined surfaces 3H and 3I are formed around the groove so as to be inclined toward the inner peripheral side and toward the distal end side.
[0011]
In the recess 3 formed in this way, in this embodiment, a diameter-enlarging bit 4 as shown in FIGS. 6 and 7 is fitted to the center of the hole 3G eccentric from the axis O by fitting the shaft hole into the hole 3G. 2 and 3, when it is rotated clockwise about the central axis X in FIGS. 2, 3, 5, and 7, As shown in the figure, the outer diameter from the axis O is positioned in a state where the outer diameter is enlarged. On the contrary, when it is rotated in the counterclockwise direction, as shown in FIG. Is smaller than or equal to the outer diameter of a portion on the distal end side of the step portion 1C of the distal end portion 1A of the device 1. Therefore, in the present embodiment, the recess 3 also serves as a space for accommodating the enlarged diameter bit 4 in a state where the enlarged diameter bit 4 is reduced in diameter.
[0012]
The enlarged diameter bit 4 is formed into a thick block-shaped main body 4A having a substantially sector shape when viewed in the direction of the central axis X, and protrudes from the front and rear end surfaces 4X and 4Y of the main body 4A when the shaft hole is fitted as described above. A substantially columnar shaft 4B, 4C extending around the center axis X is integrally formed, and the shaft 4C protruding to the rear end side (the right side in FIG. 6) is the front end side (FIG. 6). The shaft 4C is longer and has a larger diameter than the shaft 4B protruding to the left (in FIG. 2), and the shaft 4C is rotatably fitted into the hole 3G to be fitted into the shaft hole. The shaft 4C protruding toward the rear end has a length protruding from the rear end surface 4Y of the main body 4A equal to the depth of the hole 3G, and as shown in FIG. Is in contact with the bottom surface 3Z of the hole 3G, the rear end surface 4Y of the main body 4A can contact the bottom surface 3F of the concave portion 3. The main body 4A has a side surface 4D for positioning the enlarged diameter bit 4 by abutting the wall surface 3A of the concave portion 3 in a state where the enlarged diameter bit 4 is enlarged, and a center axis X centered on the side surface 4D. A side surface 4F smoothly connected via a convex cylindrical surface 4E, a side surface 4G that bends in a direction intersecting the side surface 4F at an obtuse angle, and a convex cylindrical surface connecting the side surfaces 4G and 4D. And a side surface 4H. The side surfaces 3D to 3G are formed so as to extend in parallel with the central axis X, while the rear end portion of the side surface 4H is inclined so as to gradually recede toward the rear end side. One or more inclined surfaces are formed on the side edges of the side surfaces 4G and 4H of the front end surface 4X of the main body 4A so as to be inclined toward the rear end side toward the side surfaces 4G and 4H. Side 4G and side 4H, and side Each intersection ridge line between 4H and side 4D are chamfered.
[0013]
Further, the radius of the convex cylindrical surface formed by the side surface 4E is set to a size capable of slidingly contacting the wall surface 3B forming the concave cylindrical surface when the shaft 4C is inserted into the hole 3G of the concave portion 3. As shown in FIG. 2, the convex cylindrical surface forms a part of a cylindrical surface having a diameter larger than the outer diameter of the casing or the casing top around the axis O in a state where the diameter-expanding bit 4 is expanded. Have been. A large number of button-shaped chips 5 made of a hard material such as a cemented carbide are implanted on the inclined surface of the distal end surface 4X of the main body 4A of the enlarged diameter bit 4 and the periphery thereof. By rotating together with the device 1 in the rotation direction T in a state where the diameter of the hole 4 is enlarged, the outer peripheral side of the hole is excavated by these chips 5. In addition, on the front end surface 4X of the main body 4A, a disk having the same diameter as the cylindrical surface formed by the side surface 4E about the center axis X is formed around the rear end of the shaft 4B protruding from the front end surface 4X. In this case, a step 4I that is convex on the tip side is formed, and the projecting height of the chips 5... Is set to a size not exceeding the step 4I. The angle between the side surface 4D and the side surface 4F sandwiching the side surface 4E of the enlarged diameter bit 4 is smaller than the angle between the wall surface 3A and the wall surface 3C of the concave portion 3 sandwiching the wall surface 3B. The angle between the inner wall and the side surface 4G is equal to the included angle between the wall surface 3C and the wall surface 3D, and when the diameter-enlargement bit 4 is reduced in diameter, as shown in FIG. , The main body 4A is housed in the recess 3 as described above, and the outer diameter thereof is reduced.
[0014]
Furthermore, the device 1 is formed with a through-hole 6 having a circular cross section along the axis O from the rear end 1B to the tip 1A, and the through-hole 6 has an inner diameter in the tip 1A. The diameter is increased by one step so as to open to the front end face 1E with a constant inner diameter, and the enlarged part is used as a mounting hole 6A for a pilot bit 7 described later. Here, a pair of pin holes 6B, 6B extending in a tangential direction of a circle formed by the mounting hole 6A in a cross section orthogonal to the axis O are provided at the distal end 1A of the device 1 between the axis O as shown in FIG. Are formed in parallel with each other, and are shifted stepwise in the direction of the axis O as shown in FIG. One end of each of the pin holes 6B, 6B is opened at the bottom of a pair of the discharge grooves 2A, 2A located on opposite sides of the axis O, and a circle formed by the mounting hole 6A from this one end. The portion beyond the contact point is a large-diameter portion, and a portion smaller than the large-diameter portion through a step portion that reduces the diameter by one step is opened so that the other end is open to the outer peripheral surface of the distal end portion 1A of the device 1. At the point of contact with the circle, a substantially semicircular portion on the axis O side of a circle formed by the cross section of the pin hole 6B overlaps with the mounting hole 6A and opens on the inner peripheral surface of the mounting hole 6A. It has been like that.
[0015]
The through-hole 6 further has four smaller-diameter branch holes 6C branching from the small-diameter portion before reaching the mounting hole 6A, as shown in FIG. As shown in FIG. 5, they are formed at equal intervals in the circumferential direction so as to open at the bottoms of the discharge grooves 2A. Further, exhaust holes 6D are branched from the middle of these branch holes 6C so as to be slightly inclined toward the rear side in the rotation direction T as shown in FIG. The distal end of the exhaust hole 6D is opened on the bottom surface 3F of the concave portion 3 so as to be adjacent to the rotation direction T side of the hole 3G.
[0016]
On the other hand, the pilot bit 7 attached to the attachment hole 6A constitutes a tool main body together with the device 1 in the present embodiment, and has substantially the same diameter as the distal end face 1E of the device 1 as shown in FIGS. And a thick cylindrical shaft portion 7C having a constant outside diameter protruding from the center of the back surface portion 7B of the bit body 7A. The portion 7C is fitted to the mounting hole 6A and inserted, so that the device 7 is mounted on the distal end portion 1A of the device 1 about the axis O as shown in the figure. The tip end surface of the bit main body 7A is formed so that its central portion is concave, and four concave grooves 7D are formed at equal intervals in the circumferential direction from this central portion to the outer peripheral surface of the bit main body 7A. A large number of button-shaped chips 5 made of a hard material such as cemented carbide are implanted on the tip end surface of the bit body 7A so as to avoid the above-mentioned concave grooves 7D. A pair of exhaust holes 7E, 7E are branched from the tip of the inner peripheral portion of the shaft portion 7C, and these exhaust holes 7E, 7E are opposite to each other across the axis O of the concave grooves 7D. Are opened at the center of the pair of concave grooves 7D, 7D. Further, on the outer peripheral surface of the bit body 7A, between the adjacent grooves 7D, 7D in the circumferential direction, slightly shallower grooves 7F are also formed at equal intervals in the circumferential direction.
[0017]
Further, a pair of pin grooves 7G, 7G having a semicircular cross section having substantially the same diameter as the pin hole 6B are formed on the outer peripheral portion of the shaft portion 7C so that the outer periphery of the shaft portion 7C has a cross section orthogonal to the axis O. In order to extend in the tangential direction of the circle, the pin holes 6B, 6B are displaced stepwise with a displacement equal to the displacement in the axis O direction between the pin holes 6B, 6B in the axis O direction. The shaft portion 7C is inserted into the mounting hole 6A so that the pin grooves 7G and 7G are aligned with the portions where the pin holes 6B and 6B are opened in the mounting hole 6A. Then, by inserting the pins 8, 8 into the pin holes 6B, 6B and locking and fixing them in the pin grooves 7G, 7G, the pilot bit 7 is positioned in the circumferential direction and is prevented from falling off to the distal end side. It has been made to be. The portion around the shaft 7C on the inner peripheral side of the back surface portion 7B of the bit main body 7A is in a state where the shaft 7C of the pilot bit 7 is thus prevented from falling out and attached to the mounting hole 6A as shown in FIG. An annular flat surface that can be in close contact with the tip surface 1E of the device 1 is provided.
[0018]
On the back surface 7B of the bit main body 7A, a convex portion 9 that can be fitted to the concave portion 3 formed on the outer periphery of the distal end portion 1A of the device 1 is formed integrally with the bit main body 7A. Here, in the present embodiment, in the state where the pilot bit 7 is positioned in the circumferential direction as described above, four protrusions that can be fitted into each of the plurality (four) of the recesses 3 formed in the device 1. Are formed on the outer peripheral side of the back surface portion 7B at equal intervals in the circumferential direction, and each of the convex portions 9 includes a first convex portion 9A located on the rear side in the rotation direction T and a first convex portion 9A. The second projection 9B and the second projection 9B located on the rotation direction T side at an interval in the circumferential direction respectively constitute two projections 9A and 9B.
[0019]
Among them, the first protrusions 9A of the protrusions 9 are fitted into the recesses 3 of the device 1 with the shaft 7C of the pilot bit 7 positioned and fitted in the mounting holes 6A of the device 1. Are formed to protrude from the back surface portion 7B so as to form a thick cylindrical shape coaxial with the central axis X of the hole 3G, and the outer diameter of the cylindrical shape formed by the first convex portion 9A is: The outer peripheral surface is sized to be able to adhere to the inner periphery of the concave cylindrical surface formed by the wall surface 3B of the concave portion 3. On the other hand, the second convex portion 9B is formed in a convex wall shape protruding rearward from the back surface portion 7B at a position substantially equal to the concave groove 7F in the circumferential direction, and the wall surface 9C facing the rotation direction T side. Is formed in a convexly bent surface shape which can be in close contact with the concavely bent wall surfaces 3D and 3E of the concave portion 3 in a state where the pilot bit 7 is also positioned and fitted to the device 1. Therefore, the first convex portion 9A is fitted into the wall surface 3B and the second convex portion 9B is brought into close contact with the wall surfaces 3D and 3E, whereby the first and second convex portions 9A and 9B are formed. The convex portion 9 is restrained by the concave portion 3 facing in the shaft hole fitting state in the rotation direction T and the rear side thereof, and fitted into the concave portion 3 as described above.
[0020]
The height of the projection 9 from the back surface 7B of the first and second projections 9A and 9B is slightly smaller than the depth from the tip surface 1E of the device 1 to the bottom of the step 1D. The hole 9D defined by the inner peripheral portion of the cylinder formed by the first convex portion 9A has an inner diameter and a depth at which the shaft 4B protruding toward the distal end side of the enlarged diameter bit 4 can be inserted. In a state where the pilot bit 7 is positioned and fitted to the device 1, the enlarged diameter bit 4 is fitted with the shafts 4B and 4C projecting from the front and rear ends thereof into the holes 9D and 3G. The rear end face 3Y of the main body 4A and the rear end face 4Z of the shaft 4C were restrained in the direction of the central axis X, that is, the direction of the axis O, and were brought into contact with the bottom face 3F of the recess 3 and the bottom face 3Z of the hole 3G, respectively. Sometimes, as shown in FIG. 1, the tip of the step 4I and the shaft 4B There is a slight gap between the surface and the rear end face of the first protrusion 9A and the hole bottom of the hole 9D, so that the main body 4A and the bit 5 do not interfere with the protrusion 9 and the central axis X It is supported so that it can rotate around. Therefore, in the present embodiment, the first convex portion 9A formed in a cylindrical shape of the convex portion 9 is directed toward the rear end around the hole 9D fitted with the shaft 4B of the diameter-enlarging bit 4 in the shaft hole. It is formed so as to protrude.
[0021]
However, as shown in FIG. 10, the inner peripheral side portion of the back surface portion 7B of the first convex portion 9A is formed as the inner peripheral side of the back surface portion 7B is formed in an annular flat surface as described above. A portion overlapping the outer peripheral side of the flat surface is formed so as to be cut out in a concave arc surface centered on the axis O, and a portion of the first convex portion 9A on the outer peripheral side of the back surface portion 7B is formed by the concave portion. The groove 7F is cut out in a concave arc shape having a smaller radius than the inner peripheral portion. The outer peripheral portion of the second convex portion 9B is also notched by the concave groove 7D. On the other hand, on the outer peripheral portion of the back surface portion 7B between the first convex portion 9A and the second convex portion 9B in each convex portion 9, an inclined surface 7H inclined toward the rear end side toward the inner peripheral side. Is formed, and the outer peripheral portion of the back surface portion 7B other than the first and second convex portions 9A and 9B is a flat surface flush with the annular surface on the inner peripheral side.
[0022]
In the present embodiment, the outer peripheral portion of the shaft 4B on the distal end side of the diameter-enlarged bit 4 fitted in the shaft hole and the cylindrical first convex portion 9A of the convex portion 9 fitted with the shaft 4B. Collars 10A and 10B are attached to the inner peripheral portion of the peripheral hole 9D. Further, these collars 10A and 10B have a higher hardness than the material forming the enlarged bit 4 and the pilot bit 7 in which the shaft 4B and the hole 9D are formed. 7 may be different from the material of the same material. For example, even when the material of the enlarged diameter bit 4 and the pilot bit 7 is a steel material, the same kind of material is used, such as that the collars 10A and 10B are made of a harder steel material. You may. In the present embodiment, both the collars 10A and 10B are cylindrical, and are attached to the outer peripheral portion of the shaft 4B and the inner peripheral portion of the hole 9D by shrink-fitting or the like so that the enlarged bit 4 rotates. At this time, the collar 10A attached to the shaft 4B rotates integrally with the shaft 4B so that the outer periphery thereof and the inner periphery of the collar 10B on the side of the hole 9D slide.
[0023]
In the drilling tool configured as described above, first, the outer peripheral portion of the shaft 4B on the tip end side of the diameter-enlarging bit 4 rotatable by the shaft hole fitting, and the pilot on the tool body side into which the shaft 4B is inserted. The collars 10A and 10B are attached to the inner peripheral portion of the hole 9D formed in the bit 7, so that the shaft 4B and the hole 9D are worn while the diameter expanding bit 4 repeatedly expands and contracts the diameter. Even if the wear occurs on the collars 10A and 10B, the shaft 4B of the enlarged diameter bit 4 and the hole 9D of the pilot bit 7 do not wear. For this reason, when the enlarged diameter bit 4 rattles due to such wear, by removing the pilot bit 7 and the enlarged diameter bit 4 and replacing the collars 10A and 10B, the outer periphery of the shaft 4B and the hole 9D are immediately formed. It is possible to restore the initial shaft hole fitting state in which the inner circumference can be closely contacted and slid, and the enlarged diameter bit 4 and the pilot bit 7 (tool body) can be reused without being discarded. The tool life can be extended, which is economical.
[0024]
Further, in the present embodiment, the collars 10A and 10B have a higher hardness than the material constituting the enlarged bit 4 in which the shaft 4B is formed and the pilot bit 7 in which the hole 9D is formed. When the diameter bit 4 rotates about the central axis X, these high-hardness collars 10A and 10B only slide between the shaft 4B and the hole 9D. Even if the diameter of the collar 4 is frequently increased and decreased, the wear itself of the collars 10A and 10B can be suppressed and a gap can be prevented from being formed between the shaft portion 4B and the inner and outer circumferences of the hole 9D. For this reason, according to the present embodiment, the frequency of replacing the collars 10A and 10B due to such wear can be extremely reduced, and rattling of the enlarged diameter bit, breakage of the shaft 4B, and the like over a long period of time. Thus, it is possible to reliably prevent the rotation and stably support the enlarged diameter bit 4 so as to promote smooth excavation.
[0025]
In addition, in the present embodiment, the collars 10A and 10B are fitted with the outer peripheral portion of the shaft 4B on the front end side having a small outer diameter among the shafts 4B and 4C protruding from the front and rear ends of the enlarged diameter bit 4. The small-diameter shaft 4B and the hole 9D, which are attached to the inner peripheral portion of the hole 9D, that is, the change rate of the shaft diameter or the hole inner diameter due to wear is large even with the same amount of wear, and the holes 9D are protected by the collars 10A and 10B. Therefore, the life of the bit 4 can be more effectively extended. However, a collar may be provided on the outer and inner peripheral portions of the large-diameter shaft 4C and the hole 3G protruding toward the rear end, and provided on both the front and rear shafts 4B and 4C and the holes 9D and 3G. Of course, it does not matter. Further, when the outer diameters of the shafts 4B and 4C and the holes 9D and 3G have to be limited, the outer peripheral portions of the shafts 4B and 4C and the holes 9D are similar to the second and third embodiments described later. , 3G may be provided with a collar only on one of the inner peripheral portions.
[0026]
On the other hand, in this embodiment, the tool main body is composed of the device 1 and the pilot bit 7 mounted on the axis O thereof and protruding toward the front end side. Since the periphery of the small diameter drilled hole is excavated by the enlarged diameter bit 4, the excavation efficiency can be improved as described above, and the enlarged diameter bit 4 has a shaft protruding from the front and rear ends thereof. Since both ends are supported by fitting the holes 4B and 4C into the holes 9D of the pilot bit 7 and the holes 3G of the device 1, it is possible to achieve more stable excavation. Further, in the present embodiment, the pilot bit 7 is attached by inserting the cylindrical shaft portion 7C into the mounting hole 6A of the device 1 and inserting the pilot shaft 7 into the pin 7C. Since the pins 8, 8 are locked in the grooves 7G, 7G, they are prevented from coming off, so that, for example, when the shaft portion is attached by screwing with screws, the impact given to the device 1 from the hammer is given. The screw does not loosen due to the impact due to the force, so that the support of the pilot bit 7 becomes unstable or play does not occur between the shaft portion 7C and the mounting hole 6A. Can prevent the shaft portion 7C from being broken. On the other hand, a concave portion 3 and a convex portion 9 that can be fitted to each other are formed on the distal end portion 1A of the device 1 and the back surface portion 7B of the bit body 7A of the pilot bit 7 facing the distal end portion 1A. Since the pilot bit 7 is constrained in the circumferential direction of the device 1 and firmly held by the fitting of the concave and convex portions 3 and 9, the rotational force transmitted to the pilot bit 7 via the device 1 during excavation is also reduced. A high mounting rigidity can be secured to the pilot bit 7, and a situation in which the shaft portion 7C is twisted by this rotational force to damage the pin groove 7G, the pin 8, or the shaft portion 7C itself is prevented. As a result, the torque can be reliably transmitted to the pilot bit 7 and a smooth excavation can be achieved.
[0027]
Particularly, in the present embodiment, a plurality of the concave and convex portions 3 and 9 are formed at equal intervals in the circumferential direction so as to be fittable, and these convex portions 9 are formed on the bit body 7A of the pilot bit 7. Since the bit body 7A is formed on the outer peripheral side of the back surface portion 7B, the bit body 7A can be more firmly held against the rotational force around the axis O, and the rigidity can be further improved. Further, the convex portion 9 is constituted by first and second convex portions 9A and 9B which are spaced from each other in the circumferential direction, and the cylindrical first convex portion 9A is located on the rear side of the concave portion 3 in the rotation direction T. And the second convex portion 9B having a convex wall shape can be brought into close contact with the wall surfaces 3D and 3E located on the rotation direction T side. The first and second projections 9A and 9B can be distributed and received by the first and second projections 9A and 9B, and the first projection 9A, which is located on the rear side in the rotation direction T during excavation and exerts a large rotational force, has high rigidity. Because of the cylindrical shape, smoother and more stable excavation can be promoted.
[0028]
In addition, in the present embodiment, the main body 4A of the diameter-enlarging bit 4 can be accommodated in the recess 3 when the diameter-enlarging bit 4 rotates around the central axis X and expands and contracts as described above. That is, the concave portion 3 fitted with the convex portion 9 on the pilot bit 7 side is also used as a space for accommodating the enlarged diameter bit 4. Therefore, when forming a recess for fitting the pilot bit 7 and the device 1, the thickness of the device 1 does not need to be greatly reduced, thereby increasing the rigidity of the device 1 to which the protrusion 9 fits. Pilot bit 7 can be more securely secured, and pilot bit 7 can be held more firmly.
[0029]
Furthermore, in the present embodiment, the shafts 4B and 4C from which the diameter-expanding bit 4 projects at the front and rear ends thereof are formed with holes 9D formed in the back surface portion 7B of the pilot bit 7 and holes formed in the concave portion 3 of the device 1. 3G is rotatable around the central axis X by fitting into a shaft hole, and a first protrusion 9A of the protrusion 9 is a cylindrical member having a hole 9D on the pilot bit 7 side as an inner periphery. And protrudes around the hole 9D. Therefore, according to the present embodiment, the shaft 4B of the enlarged diameter bit 4 that is rotatably supported by being inserted into the hole 9D is supported by the first convex portion 9A up to the root portion near the main body 4A. As a result, the mounting rigidity of the enlarged diameter bit 4 can be sufficiently ensured, and the mounting rigidity of the pilot bit 7 can be ensured by fitting the concave and convex portions 3 and 9 as described above. Together, these bits 4 and 7 enable smoother and more stable excavation.
[0030]
Further, in the present embodiment, when the enlarged diameter bit 4 rotatably fits the shafts 4B and 4C into the shaft holes 9D and 3G, the shaft protruding from the rear end face 4Y of the main body 4A as described above. When the rear end face 4Z of the 4C comes into contact with the bottom face 3Z of the hole 3G, the projection length of the shaft 4C is equal to the depth of the hole 3G so that the rear end face 4Y can come into contact with the bottom face 3F of the concave portion 3. When the excavating tool advances during excavation, the rear end surfaces 4Y and 4Z are brought into close contact with the bottom surfaces 3F and 3Z, respectively, as shown in FIG. Therefore, the load and impact acting on the enlarged diameter bit 4 at the time of the forward movement are dispersed and received by the bottom surfaces 3F and 3Z of the device 1, and such a load is applied to the enlarged diameter bit 4 and particularly to the shaft 4C. It is also possible to prevent a situation in which breakage occurs due to concentration of impact or impact. Further, in the present embodiment, the shaft portion 7C of the pilot bit 7 is also fixed to the mounting hole 6A with the shaft portion 7C secured as described above, and the inner side of the back surface portion 7B of the bit body 7A. The flat surface around the shaft portion 7C can be in close contact with the distal end surface 1E of the device 1, so that the load or impact during excavation does not concentrate on at least the shaft portion 7C, and furthermore, the shaft portion 7C The pin grooves 7G, 7G formed to prevent the shaft from slipping off are formed so as to be displaced stepwise in the direction of the axis O, and the cross-sectional area of the shaft portion 7C may be largely shaved by the pin grooves 7G, 7G. Therefore, the breakage and the like can be more reliably prevented in combination with the fitting of the uneven portions 3 and 9.
[0031]
In this embodiment, the concave portion 3 is formed on the device 1 side and the convex portion 9 is formed on the pilot bit 7 side. However, the convex portion is formed on the distal end portion 1A of the device 1 on the contrary. A concave portion may be formed on the back surface portion 7B of the pilot bit 7 and fitted thereto, or the device 1 and the pilot bit 7 may be formed with concave / convex portions and convex / concave portions which can be fitted to each other. It may be. In the present embodiment, the fitting of the shaft hole between the device 1 and the pilot bit 7 and the fitting of the shaft hole between the device 1 and the pilot bit 7 and the diameter-enlarging bit 4 are the same. The shafts 4B and 4C and the shaft 7C formed on the 4A and 7A are fitted into the holes 3G and 9D of the device 1 and the pilot bit 7 and the mounting holes 6A. A shaft portion is provided on the device 1 side and fitted into a mounting hole formed in the pilot bit 7, or the device 1 or the pilot bit 7 is provided with an axis centered on the central axis X to protrude the enlarged bit 4. Alternatively, it may be rotatably fitted into the hole formed in the hole. Thus, even when the enlarged diameter bit 4 and the tool body, that is, the device 1 and the pilot bit 7 are fitted in the shaft hole, the collar is attached to at least one of the outer peripheral portion of the shaft and the inner peripheral portion of the hole. Thereby, the same effect as described above can be obtained. In the case where the pilot bit 7 is provided with a shaft that fits into the hole of the diameter-enlarged bit 4 in this manner, similarly to the above-described embodiment, the convex portion 9 (the When the first convex portion 9A) is provided so as to be fitted to the concave portion 3 on the device 1 side, the convex portion 9 is formed so as to protrude around the root of the shaft. The projections and the projections form a multi-stage cylindrical shape.
[0032]
Next, FIGS. 11 to 13 show a second embodiment of the present invention, in which the tool main body is constituted only by a device without having a pilot bit as in the first embodiment. It shows the case where there is. However, also in this embodiment, as in the first embodiment, this device 11 has a substantially multi-stage outer shape in which the front end 1A is one step larger in diameter than the rear end 1B as shown in FIGS. When a hammer (not shown) is attached to the rear end portion 1B, the hammer receives a rotational force around the axis O in the direction indicated by the symbol T in the figure during excavation and also has a front end side in the direction of the axis O (FIG. 1). At the left).
[0033]
Further, the front end portion 11A has a multi-stage shape in which the rear end portion is slightly larger in diameter than the front end side, so that the outer periphery thereof has a step protruding toward the rear end side. The outer diameter of the step 11C, that is, the maximum diameter of the device 11 is set to a size that can be inserted into the inner periphery of a cylindrical casing (not shown), while being larger than the step 11C. The outer diameter of the distal end portion of the distal end portion 11A on the distal end side is set to a size that can be inserted into the inner periphery of the cylindrical casing top, which is one step smaller in inner diameter, which is attached to the forefront of the casing. By contacting the rear end of the casing top, only the impact force is transmitted to the casing, so that the casing moves forward and can be embedded in the drilled hole. With the step 11C abutting on the rear end of the casing top, the distal end surface 11D of the device 11 slightly projects from the front end of the casing top. However, the step portion 1D as in the first embodiment is not formed around the distal end surface 11D.
[0034]
On the outer periphery of the distal end portion 11A of the device 11, a discharge groove 12A of the large-sized dust in the circumferential direction and a small discharge groove 12B adjacent to the rotation direction T side thereof are parallel to the axis O. A plurality of pairs (three pairs in this embodiment) of the pair of discharge grooves 12A and 12B are positioned at equal intervals in the circumferential direction so as to extend from the distal end surface 11D to the rear end of the distal end portion 11A. It is formed so that. Further, of the pair of scouring powder discharge grooves 12A, 12B,..., 12B, the distal end face 11D of the discharge groove 12A located on the rear side in the rotation direction T (clockwise direction in FIGS. 2 and 3). A concave portion 12D having a bottom surface 12C which is inclined toward the inner peripheral side toward the distal end is formed in the opening to communicate with the discharge groove 12A.
[0035]
A hole 13 having a center axis X parallel to the axis O at a position eccentric to the outer circumference from the axis O is formed in the distal end face 11D of the device 11. In this embodiment, the hole 13 is formed. The collar 14 is attached only to the inner peripheral portion of the reference numeral 13. Here, in the present embodiment, the holes 13 are formed in a multi-stage shape in which the front end side is larger in diameter by one step than the rear end side, and a plurality (three in the present embodiment) of the holes 13. Are formed at equal intervals in the circumferential direction of the device 11 so as to be located between the adjacent discharge grooves 12A, 12A, and substantially in the middle of the radius of the device 11 from the axis O. The collar 14 is formed in a substantially cylindrical shape having an outer diameter substantially equal to the large diameter portion 13A on the front end side of the hole 13 and an inner diameter substantially equal to the small diameter portion 13B on the rear end side. The inner periphery of the collar 13 is attached to the inner periphery of the diameter portion 13A by shrinkage fitting, cooling shrinkage, press-fitting, or the like. It will be located on the same circumferential surface as the circumference. However, at the rear end of the inner periphery of the collar 14, there is formed an annular stepped portion 14A which is recessed toward the outer periphery, and a small gap is provided between the inner periphery and the small diameter portion 13B in a state where the collar 14 is attached to the hole 13. The collar 14 is provided with a tapered chamfer 14B extending toward the outer peripheral side on the distal end side of the inner periphery of the collar 14, and further, the distal end of the collar 14 is attached to the distal end surface of the device 11 in this attached state. It is disposed at a position flush with or slightly retracted from the hole 13 with the hole 11D. The hardness of the collar 14 is higher than that of the device (tool body) 11 in which the hole 13 to which the collar 14 is attached is formed.
[0036]
The tip 11A of the device 11 has a tangent to a circle formed by the small-diameter portion 13B of the hole 13 in a plane perpendicular to the axis O in a direction perpendicular to the axis O from the outer periphery toward the inner periphery. Are formed so as to be positioned on the rotation direction T side of each of the holes 13. Each of the pin holes 11E overlaps with the small diameter portion 13B of the hole 13 at the contact point with the circle. A substantially semicircular portion on the center axis X side of a circle formed by the cross section of the pin hole 11E is opened in the hole 13. Further, the device 11 is formed with a compressed air exhaust hole 11F from the rear end 11B along the axis O, and the distal end side of the exhaust hole 11F penetrates the device 11 along the axis O. As shown in FIGS. 1 and 3, the exhaust hole 11F is opened at the center of the distal end surface 11D, and the exhaust hole 11F branches off in the middle to form the bottom surface 12C of the concave portion 12D and the step 11C on the outer periphery of the distal end portion 11A. It is also opened at the front end side and at the bottom of the hole 13.
[0037]
On the other hand, in the present embodiment, the enlarged diameter bit 15 attached to the distal end side of the device 11 is a thick flat plate whose main body 15A has a substantially sector shape as viewed from the distal end as shown in FIGS. A large number of button-side chips 16 made of a hard material such as a hard alloy are implanted on a front end face 15B of the main body 15A, and a rear end face 15C of the main body 15A is formed in a planar shape perpendicular to the axis O. A cylindrical shaft 15D is formed integrally with the main body 15A so as to protrude perpendicularly from the rear end surface 15C to the rear end side, and is formed integrally with the main body 15A. The number of such large-diameter enlarged bits 15 is equal to the number of holes 13 (three in this embodiment), and each of the shafts 15D is fitted into the hole 13 to which the collar 14 is attached, and is rotated around the central axis X. Take it possible It has been kicked. The shaft 15D is inserted into the hole 13 in the central axis X direction in a state where the shaft 15D is inserted into the hole 13 and the rear end face 15C of the main body 15A is in close contact with the front end face 11D of the device 11 as described above. An annular groove 15E having a semicircular cross section having the same diameter as a circle formed by the cross section of the pin hole 11E is formed at a position corresponding to the pin hole 11E so as to orbit around the central axis X. By matching the positions of the groove 15E and the pin hole 11E and inserting and fixing the pin 17 in the pin hole 11E, the diameter-enlarging bit 15 becomes a pin protruding from a portion of the pin hole 11E that opens into the hole 13. The outer periphery of 17 is engaged with the annular groove 15E to prevent the shaft 15D from coming off, and the main body 15A is supported rotatably around the central axis X as described above.
[0038]
Note that the fan shape formed by the main body 15A is a biased shape, that is, one of two sides intersecting the center (a main part of the fan) is a long side and the other is a short side shorter than this. In addition, the arc-shaped side connecting the tips of these two sides is such that the portion on the long side has an arc shape having a radius from the center larger than that of the casing or the casing top. The portion on the short side is constituted by an arc and a straight line having a radius substantially equal to the outer diameter (radius) of the portion on the tip side from the step 11C of the tip portion 11A in order toward the short side. The distance to the center is gradually reduced toward the short side. The sector angle of the sector, that is, the intersection angle of the long and short sides is a value obtained by dividing 360 ° by the number of the diameter-enlarging bits 15, and is 120 ° in the present embodiment.
[0039]
Thus, when the device 11 receives a rotational force in the rotation direction T during excavation, the enlarged bits 15 supported rotatably about the central axis X as shown in FIG. As shown in the figure, a side surface of the main body 15A of the enlarged diameter bit 15 which rotates in the clockwise direction around the central axis X and which is adjacent to the circumferential direction and located on the rotation direction T side is connected to the short side in the rotation direction T. The abutment of the main body 15A of the main body 15A of the large diameter bit 15 located on the rear side with the central side of the sector is formed on the axis O. And the side portion of the main body 15A separated from the center is positioned in an enlarged state so as to protrude outward from the casing or the casing top, and is positioned larger than the casing outer diameter. To form a drilling diameter. At this time, the discharge grooves 12A and 12B of the device 11 and the concave portion 12D communicating with the discharge groove 12A are provided on the rotation direction T side of the side surface connected to the long side of each of the enlarged bits 15 in the front view. It is made to open. When the device 11 is rotated backward in the rotation direction T after the excavation is completed, the enlarged diameter bits 15 rotate counterclockwise around the central axis X as shown in FIG. The abutting side surface of the diameter-enlarging bit 15 that is located on the opposite side contacts the portion of the side surface that is located on the rear side in the rotation direction T and that is continuous with the long side of the diameter-enlarging bit 15 and that is opposite to the center. Since the main body 15A of the diameter bit 15 is positioned with its diameter reduced so as to fit within the distal end surface 11D of the device 11 when viewed from the front, only the excavating tool can be pulled out from the casing by retracting the entire device 11 as it is. .
[0040]
Therefore, also in the excavating tool of the second embodiment configured as described above, the collar 14 is provided on the inner peripheral portion of the hole 13 of the device (tool main body) 11 into which the shaft 15D of the diameter-enlarging bit 15 is rotatably fitted. Since the wear on the side of the hole 13 occurs in the collar 14, the device 11 can be restored to the original fitted state without damage to the device 11 by replacing it. Further, since the collar 14 has a higher hardness than the device 11 in which the holes 13 are formed, the wear itself of the collar 14 can be reduced, and as a result, an economical drilling tool having a long tool life can be provided. be able to. Moreover, in such a drilling tool, the diameter-enlarging bits 15 are used for excavating with a large number of tips 16 implanted on the distal end face 15B of the main body 15A. Originally, the life of the device 11 is shorter than that of the device 11 because of wear due to excavation. On the other hand, the device 11 can be reused as it is even if the enlarged diameter bit 15 is replaced. A collar 14 is provided on the inner circumference of the device 13, so that the device 11 is prevented from being damaged, so that it can be reliably reused, which is more economical. However, even in such an excavating tool, a collar may be attached to the outer periphery of the shaft 15D, or a collar may be attached only to the outer periphery of the shaft 15D.
[0041]
FIGS. 14 and 15 show a third embodiment of the present invention. The third embodiment has a basic configuration similar to that of the second embodiment. Therefore, the same components as those of the second embodiment are denoted by the same reference numerals, and description thereof is omitted. That is, in the second embodiment, the collar 14 is attached to the inner peripheral portion of the hole 13 formed in the device (tool main body) 11 by shrink fitting, cooling shrinking, press fitting, or the like. The embodiment is characterized in that the collar 18 is attached to the inner peripheral portion of the hole 13 by an attachment member. In this embodiment, the mounting member is a set screw 19, and a counterbore portion 13C having a larger diameter than the large diameter portion 13A is formed on the distal end surface 11D side of the hole 13 formed in the device 11. A plurality of screw holes (not shown) into which the set screw 19 can be screwed are formed at equal intervals in the circumferential direction on the bottom surface of the counterbore portion 13C.
[0042]
On the other hand, the collar 18 in the present embodiment has a shape in which a flange portion 18B whose diameter is increased toward the outer periphery is integrally formed on the outer periphery of the distal end portion of a cylindrical main body 18A as shown in FIG. The flange portion 18B has an outer diameter and a thickness that can be accommodated in the counterbore portion 13C, and the through holes 18C through which the set screws 19 are inserted are formed at the same pitch as the screw holes. 13 has an outer diameter that can be inserted into the large-diameter portion 13A and an inner diameter equal to the small-diameter portion 13B of the hole 13. Thus, the main body 18A is inserted into the large-diameter portion 13A and then inserted into the through hole 18C. By screwing a set screw 19 into the screw hole, the collar 18 is attached and fixed to the inner peripheral portion of the hole 13. In this mounting state, the end surface of the flange portion 18B and the head of the set screw 19 do not protrude beyond the distal end surface 11D of the device 11. Also, a tapered chamfer 18D is formed on the front end side of the inner peripheral portion of the collar 18 like the collar 14 of the second embodiment, but a step is not formed on the rear end side. The inner periphery of the collar 18 is flush with the small diameter portion 13B of the hole 13.
[0043]
However, in the first and second embodiments, the collars 10A, 10B, and 14 are strongly adhered to the outer peripheral portion of the shaft 3B and the inner peripheral portions of the holes 9D and 13 by shrinkage fitting, cooling fitting, press fitting, and the like. When the worn collars 10A, 10B, 14 are to be removed for replacement or the like, the collars 10A, 10B, 14 are cut and peeled off from the outer periphery of the shaft 3B or the inner periphery of the holes 9D, 13 or the pulley is pulled out. On the other hand, in the third embodiment, the collar 18 can be removed only by loosening the set screw 19, and when a new collar 18 is attached, the set screw 19 only needs to be screwed. Therefore, the replacement work is extremely easy and efficient. In this embodiment, the set screw 19 is used as the mounting member in this manner. For example, the pin is used as the mounting member in the same manner as in the first embodiment in which the shaft portion 7C of the pilot bit 7 is prevented from coming off. Alternatively, the collar may be attached by using.
[0044]
【The invention's effect】
As described above, according to the present invention, in an excavating tool in which a diameter-enlarging bit is rotatably supported by being fitted to a tool body in a shaft hole, the outer peripheral portion of the shaft and the inner peripheral portion of the hole fitted to each other. By attaching a collar to at least one of the two, even if abrasion occurs, it is possible to return to the initial fitting state simply by replacing this collar, and the expanded bit and the tool body itself can be reused, so that economical Excavation work can be planned. Furthermore, by making this collar harder than the tool body and the expanding bit, the wear itself of the collar can be suppressed, preventing rattling of the expanding bit and breakage of the shaft for a long time. Excavation can be performed stably, and the economic efficiency can be further improved.
[Brief description of the drawings]
FIG. 1 is a partially cutaway side view showing a first embodiment of the present invention.
FIG. 2 is a partially cutaway front view of the embodiment shown in FIG.
FIG. 3 is a partially cutaway front view of the embodiment shown in FIG.
FIG. 4 is a side sectional view showing the device 1 of the embodiment shown in FIG. 1 (however, a rear end portion 1B is not shown).
FIG. 5 is a front view of the device 1 shown in FIG.
FIG. 6 is a side view of the enlarged diameter bit 4 of the embodiment shown in FIG. 1 (however, a chip 5 is not shown).
7 is a front view of the enlarged diameter bit 4 shown in FIG.
8 is a side sectional view of a pilot bit 7 of the embodiment shown in FIG. 1 (however, a chip 5 is not shown).
FIG. 9 is a front view of the pilot bit 7 of the embodiment shown in FIG.
FIG. 10 is a rear view of the pilot bit 7 of the embodiment shown in FIG. 1 as viewed from the rear end.
FIG. 11 is a partially cutaway side view showing a second embodiment of the present invention.
12 is a front view of the embodiment shown in FIG.
FIG. 13 is a front view of the embodiment shown in FIG.
FIG. 14 is a partially cutaway side view showing a third embodiment of the present invention.
FIG. 15 is a perspective view showing the collar 18 of the embodiment shown in FIG.
[Explanation of symbols]
1,11 devices (tool body)
3G, 9D, 13 holes
4,15 expanding bit
4B, 4C, 15D Shafts of enlarged bits 4 and 15
7 Pilot bit (tool body)
10A, 10B, 14, 18 colors
19 Set screw (Mounting member)
O Axis of devices 1 and 11
X Center axis of enlarged bits 4 and 15
T Rotation direction of devices 1 and 11 during excavation

Claims (3)

Excavation in which an enlarged bit that is rotatable about a central axis eccentric from the axis and positioned in a state where the outer diameter from the axis is enlarged is attached to the outer periphery of the tip end of the tool body that is rotated about the axis. In the tool, the enlarged diameter bit is rotatably attached to the tool body by fitting a shaft extending along the central axis with a hole, and at least one of an outer peripheral portion of the shaft and an inner peripheral portion of the hole. A drilling tool characterized in that a collar is attached to the drilling tool. The excavating tool according to claim 1, wherein the collar has a higher hardness than at least one of an outer peripheral portion of the shaft and an inner peripheral portion of the hole. The excavating tool according to claim 1, wherein the collar is detachably attached to at least one of an outer peripheral portion of the shaft and an inner peripheral portion of the hole by an attachment member.

Images