JP4949756B2 - Expanded excavation bucket - Google Patents

Description

  The present invention relates to an enlarged diameter excavation bucket that forms an intermediate enlarged portion in the middle of a pile hole.

  With the increase in size and height of buildings, high vertical support performance is required for foundation piles. Then, as shown in FIG. 25, the cast-in-place concrete pile which expands the front-end | tip part 202 of the foundation pile 200 and enlarges a vertical support force is employ | adopted.

  Furthermore, as shown in FIG. 26, a cast-in-place concrete pile is proposed in which an intermediate enlarged portion 208 having an enlarged diameter is provided not only at the tip end portion 206 of the foundation pile 204. In this pile, since the intermediate enlarged diameter portion 208 functions like a screw thread in the ground, it is possible to obtain a large vertical support force and pulling resistance force from the surrounding ground.

  Cast-in-place concrete piles such as those shown in Figs. 25 and 26 provide sufficient vertical support and pull-out resistance even if the pile diameter is reduced. The liquid can be reduced and the environmental load can be reduced.

  Moreover, since concrete and a reinforcing bar which are pile materials can be reduced, cost reduction and construction period shortening can be aimed at.

  In the split bucket rotary excavator 212 of Patent Document 1 shown in FIG. 27A, a rectangular tube shape slidably fitted inside a rectangular tube-shaped outer tube 216 connected to the lower end of the kelly bar 214. The inner cylinder 218 is provided. A bottom plate 220 having a bit (not shown) disposed on the lower surface is horizontally attached to the lower end of the inner cylinder 218.

  Inside the outer cylinder 216, a hydraulic cylinder 226 whose rear end is rotatably connected to the top of the outer cylinder 216 is provided, and a pin 230 provided at the tip of the piston rod 228 of the hydraulic cylinder 226 is provided. Since the front end portion of the piston rod 228 and the lower end portion of the inner cylinder 218 are connected, the inner cylinder 218 expands and contracts when the piston rod 228 of the hydraulic cylinder 226 expands and contracts.

  Around the outer cylinder 216 and the inner cylinder 218, a curved side wall plate 222 having a bit (not shown) disposed on the outer wall surface is provided. The outer cylinder 216, the inner cylinder 218, and the curved side wall plate 222 are provided. They are connected by a parallel link mechanism 224.

  Therefore, when the piston rod 228 of the hydraulic cylinder 226 is in the longest state, the curved side wall plate 222 is translated inward by the action of the parallel link mechanism 224, so that the diameter of the bucket is minimized as shown in FIG. .

  Then, the split bucket rotary excavator 212 in this state is placed on the bottom of the pile hole that expands the bottom, and the rotary bucket rotary excavator 212 is rotated via the kelly bar 214 by a rotation driving device (not shown) and hydraulic pressure is increased. When the split bucket type rotary excavator 212 is lowered while the piston rod 228 of the cylinder 226 is contracted, the pile hole is expanded to the bottom, and the split bucket type rotary excavator 212 is fully opened as shown in FIG. .

  However, when the intermediate diameter enlarged portion 208 in FIG. 26 is excavated using the split bucket rotary excavator 212, the curved side wall plate 222 has a dedicated shape in accordance with the shape of the expanded bottom portion. The inclined surface 208 </ b> A below the intermediate enlarged diameter portion 208 cannot be excavated using the bit disposed on the curved side wall plate 222.

  In addition, the inclined surface at the lower portion of the intermediate enlarged diameter portion is not limited to one inclination angle, and must be capable of excavation at various inclination angles depending on the design of the pile.

The inclined surface at the lower part of the intermediate expanded portion prevents collapse of the bottom of the excavated intermediate expanded portion and prevents the slime in the hole wall stabilizing liquid from accumulating. The excavation accuracy of is a structural part that plays an important role in the quality of cast-in-place concrete piles.
JP-A-60-242292

  This invention considers the fact which concerns, and makes it a subject to provide the intermediate | middle enlarged diameter part which has a lower inclined surface in the middle of a pile hole, and to provide the bucket for extended diameter excavation with versatility.

The invention of the first aspect is provided on a rotating shaft that is suspended and rotated by an excavator body, excavates a hole wall of a vertical hole by expanding and contracting, and forms an intermediate expanded portion in the middle of the vertical hole; And an arm portion that is detachably provided at a lower end portion of the wing expansion portion and forms an inclined surface toward the center of the vertical hole at a lower portion of the intermediate diameter expansion portion.

In the first aspect of the invention, the wing expansion portion is provided on the rotating shaft suspended from the excavator body. Then, by expanding and contracting the blade expansion portion while rotating the rotation shaft, the hole wall of the vertical hole is excavated to form an intermediate diameter expansion portion in the middle of the vertical hole.

  Moreover, the arm part which can be attached or detached is provided in the lower end part of the wing expansion part. The arm portion expands and contracts while rotating together with the expanded blade portion, and forms an inclined surface toward the center of the vertical hole at the lower portion of the intermediate expanded portion.

  Therefore, it is possible to cope with excavation of various inclined surfaces at the lower portion of the intermediate expanded portion by mounting an arm portion that matches the inclined surface of the lower portion of the intermediate expanded portion to be excavated on the lower end portion of the expanded blade portion.

The invention of the second aspect is provided with a stabilizer portion that is detachably provided at a lower end portion of the rotary shaft, and that guides the center of the rotary shaft to the center position of the vertical hole by contacting the hole wall of the vertical hole. The portion is located below the arm portion.

In the invention of the second aspect , the stabilizer portion is detachably provided at the lower end portion of the rotating shaft. The stabilizer portion is located below the arm portion and contacts the hole wall of the vertical hole to guide the center of the rotation shaft to the center position of the vertical hole.

  Therefore, since the center of the rotating shaft is always at the center position of the vertical hole by the stabilizer, the roundness of the intermediate diameter-enlarged portion can be increased.

  In addition, in a normal diameter expansion excavation bucket, a stabilizer portion is provided on the rotating shaft located above the blade expansion portion, so that the intermediate diameter expansion portion can be excavated while moving the diameter expansion excavation bucket from top to bottom. When performing, since the diameter of the vertical hole excavated becomes larger than the diameter of the stabilizer portion, the stabilizer portion above the blade expansion portion does not contact the hole wall. Therefore, the stabilizer part located above the blade expansion part does not fulfill the role of guiding the center of the rotating shaft to the center position of the vertical hole.

  However, since the diameter expansion excavation bucket according to claim 2 is provided with the stabilizer portion below the arm portion, the intermediate diameter expansion portion is always excavated while moving the diameter expansion excavation bucket from the top to the bottom. The stabilizer portion below the arm portion serves as a guide, thereby increasing the roundness of the intermediate enlarged portion.

The invention of a third aspect is characterized in that the stabilizer portion is a tray.

In the invention of the third aspect , the stabilizer portion is a tray.

  Therefore, since the earth and sand excavated by the wing expansion part and the arm part can be directly received by the tray, the recovery bucket is repeatedly lowered to the bottom of the vertical hole in order to collect the excavated earth and sand that has fallen to the bottom of the vertical hole. It is not necessary to do.

  Since this invention set it as the said structure, the intermediate | middle enlarged diameter part which has a lower inclined surface can be formed in the middle of a pile hole, and the bucket for diameter expansion excavation with versatility can be provided.

  With reference to the drawings, a diameter-excavation bucket 22 according to an embodiment of the present invention will be described.

  FIG. 1 shows an overall configuration of an excavator 10 that forms an intermediate expanded portion in the middle of a pile hole 20 for constructing a cast-in-place concrete pile.

  A kelly bar 12 is connected to and suspended from a wire 88 of a crane 16 as an excavator body. Further, a turning device 14 is provided in the middle of the kelly bar 12, and the kelly bar 12 is rotated without restricting the vertical movement of the kelly bar 12.

  The positioning arm 18 projecting from the front of the crane 16 adjusts the horizontal position of the turning device 14 and arranges the kelly bar 12 at the center position of the pile hole 20 as a vertical hole.

  As shown in FIG. 9C, a shaft member 60 is connected to the upper end portion of the fixed post 24 serving as a rotating shaft. The kelly bar 12 is pin-connected to the connection bracket 26 provided on the shaft member 60.

  The pile hole 20 in FIG. 1 is formed by previously excavating the ground 28 with a drilling bucket for Keriba, and a stabilizing liquid L such as bentonite that prevents the collapse of the hole wall is contained in the pile hole 20. be satisfied.

  As shown in FIG. 2, the enlarged diameter excavation bucket 22 includes an upper stabilizer portion 36, an expansion / contraction bucket portion 38, and a lower stabilizer portion 40, which are arranged in this order from the top.

  As shown in the plan view of FIG. 3, the upper stabilizer portion 36 includes four arcuate guide members 42 that surround the shaft member 60 in a diagonal shape.

  Inside each guide member 42, the rear end portion of the rectangular tubular slide member 44 is fixed, and the front end portion of the slide member 44 faces the shaft member 60. The slide member 44 is slidably fitted inside a rectangular tube-like support member 46 projecting outward from each corner portion of the shaft member 60. Thereby, the guide member 42 can be expanded outside (the direction of arrow N) rather than the state of FIG.

  The support member 46 has two through holes 50 through which the bolts 48 pass, and the slide member 44 has seven through holes 52 through which the bolts 48 pass at equal intervals.

  The slide member 44 is slid to adjust the position of the guide member 42 to such an extent that a slight gap is left between the hole wall surface of the pile hole 20 and the guide member 42, and the through hole 50 and the through hole 52 coincide with each other. It is fixed with two bolts 48.

  At this time, by making the slide amount of each slide member 44 equal, the center of the fixed post 24 connected to the shaft member 60 can be guided to the center position of the pile hole 20.

  As shown in FIG. 2, the expansion / contraction bucket portion 38 is provided with four side wall plates 30 as wing expansion portions surrounding the fixed post 24. All of the four side wall plates 30 have the same shape, and the flat cross section of the side wall plate 30 has an arc shape. Further, the lower portion 30B of the side wall plate 30 forms a substantially vertical surface, and the upper portion 30A of the side wall plate 30 is inclined inward.

  Excavation bits 32 are arranged at equal intervals in the vertical direction at the leading end of the rotation direction of each side wall plate 30 (in the direction of arrow M). As shown in FIG. 4 of the AA sectional view of FIG. 2, the excavation bit 32 has a sharp shape toward the hole wall surface of the pile hole 20. Therefore, when the fixed post 24 is rotated in the direction of the arrow M by the turning device 14 via the kelly bar 12, and the side wall plate 30 moves to the hole wall surface side of the pile hole 20, the hole wall as the hole wall of the pile hole 20 is obtained. Is excavated to form an intermediate enlarged portion.

  An arm member 34 as an arm portion is detachably attached to the lower end portion of each side wall plate 30 in FIG. 2 so that the front end portion is directed downward and inward. The lengths of the opposing arm members 34 are the same, and the lengths of the adjacent arm members 34 are different. That is, the length of the opposing arm member 34 is long, and the length of the opposing arm member 34 is short. As a result, when the bucket diameter of the large-diameter excavation bucket 22 is minimum, the longer arm member 34 intersects, and the shorter arm member 34 does not collide with the intersecting longer arm member 34. It has become. As shown in FIG. 5, the lower portion 30 </ b> B of the side wall plate 30 forms a vertical plane substantially parallel to the vertical line 62, and the upper portion 30 </ b> A of the side wall plate 30 is inclined inward by an angle E with respect to the vertical line 62. is doing. This angle E becomes the inclination angle of the inclined surface 56A at the upper part of the intermediate expanded portion when the intermediate expanded portion 56 is excavated.

  The arm member 34 is fixed to a lower end portion of a bracket 74 provided on the inner side of the side wall plate 30 so as to be inclined inward by an angle F with respect to the vertical line 62. This angle F becomes the inclination angle of the inclined surface 56 </ b> C at the lower portion of the intermediate enlarged portion when the intermediate enlarged portion 56 is excavated.

  As shown in FIG. 6A, which is a front view of the arm member 34 shown in FIG. 5 as viewed from the outside, the arm member 34 also has the same excavation bit 58 as the excavation bit 32 of the side wall plate 30 at equal intervals in the vertical direction. It is arranged.

  As shown in FIG. 6B of the BB cross-sectional view of FIG. 6A, the excavation bit 32 has a sharp shape toward the inclined surface 56C side at the lower portion of the intermediate enlarged diameter portion. Therefore, the fixed post 24 is rotated in the direction of the arrow M by the turning device 14 via the kelly bar 12, and the arm member 34 moves outward together with the side wall plate 30, so that the hole wall of the pile hole 20 is shaved, and the intermediate diameter is increased. An inclined surface 56C at the lower part is formed.

  The arm member 34 can be attached and detached by the structure shown in FIG. Through holes 161 </ b> A and 161 </ b> B of bolts 163 are formed in the bracket 160 provided at the upper end portion of the arm member 34.

  Through holes 162A and 162B of bolts 163 are also formed in the bracket 74 provided inside the side wall plate 30, and the arm member 34 is attached to the lower end portion of the side wall plate 30 so that the bracket 160 is attached to the bracket 74. The through holes 162A and 162B coincide with the through holes 161A and 161B.

  Then, as shown in the right diagram of FIG. 7, the positions of the through holes 161A and 161B and the through holes 162A and 162B are aligned, the bolts 163 are passed, and the arm member 34 is fixed by tightening with nuts.

  The arm member 34 may be attached in any structure as long as the arm member 34 can be easily attached and detached and the hole wall of the pile hole can be firmly fixed to such an extent that the arm member 34 can be excavated, as shown in FIG. Any structure may be used.

  In FIG. 8, through holes 165 </ b> A and 165 </ b> B of the bolt 168 are formed upward in the bracket 164 provided at the upper end portion of the arm member 34.

  Through holes 167A and 167B of bolts 168 are also formed downward in the bracket 166 provided at the lower end portion of the bracket 74, and when the arm member 34 is attached to the lower end portion of the side wall plate 30, the through holes 167A, 167B coincides with the through holes 165A and 165B.

  Then, as shown in the right view of FIG. 8, the positions of the through holes 165A and 165B and the through holes 167A and 167B are aligned, the bolt 168 is passed, and the arm member 34 is fixed by tightening with the nut 169.

  The side wall plate 30 and the arm member 34 are expanded and contracted by a link mechanism 66 shown in FIG.

  As shown in FIG. 9C, the lower end portion of the kelly bar 12 is pin-connected to the connection bracket 26 on the shaft member 60. The shaft member 60 is connected to an upper end portion of a rectangular tube-shaped fixed post 24 as a rotation shaft of the diameter-excavation bucket 22.

  On the outside of the fixed post 24, a rectangular tube-shaped lifting post 64 is provided. The length of the lift post 64 is shorter than the length of the fixed post 24, and the fixed post 24 is fitted inside the lift post 64 so that the lift post 64 slides along the length direction of the fixed post 24. .

  Brackets 68 are fixed to the left and right of the elevating post 64, and a bracket 72 is provided above the bracket 68 so as to protrude further outward. The central portion of the hydraulic cylinder 70 is rotatably connected to the bracket 72.

  Both ends of the link member 76 are rotatably connected to the outer central portion of the bracket 68 and the upper portion of the bracket 74 provided inside the side wall plate 30, and are provided so as to be parallel to the link member 76. Both ends of the link member 78 are rotatably connected to the lower part of the bracket 68 and the lower part of the bracket 74.

  Both ends of the link member 80 are rotatably connected to substantially the center portions of the link members 76 and 78, and both ends of the link member 82 are provided at the lower end portion of the link member 80 and the lower end portion of the fixed post 24. Each bracket 84 is rotatably connected to each other.

  The substantially triangular bracket 90 is fixed to the link member 78 so that the bracket 90 is interlocked with the link member 78, and the top connecting portion 92 of the bracket 90 is rotatable with the tip of the piston rod 86 of the hydraulic cylinder 70. It is connected to.

  Here, when the hydraulic cylinder 70 is operated and the piston rod 86 of the hydraulic cylinder 70 is contracted in the direction of the arrow P in the state where the bucket diameter of the large-diameter excavation bucket 22 is minimum as shown in FIG. The top connection portion 92 of the bracket 90 rotates in the direction of the arrow Q with the connection portion 78A of the link member 78 connected to the bracket 68 as the rotation center.

  Then, in conjunction with the movement of the bracket 90, the link members 76 and 78 turn in the direction of arrow R, and accordingly, the lifting post 64 moves in the direction of arrow S and the side wall plate 30 moves in the direction of arrow T. Then, the state shown in FIG.

  Further, when the piston rod 86 of the hydraulic cylinder 70 is contracted in the direction of the arrow P, the bucket diameter of the expanded excavation bucket 22 is finally maximized as shown in FIG.

  Thus, by operating in the order of FIGS. 9 (A), (B), (C), the diameter-excavation bucket 22 is expanded, and the reverse operation procedure (FIGS. 9 (C), (B) ), (A)), the diameter-excavation bucket 22 is reduced in diameter.

  By such a link mechanism 66, the hydraulic cylinder 70 can be accommodated in the link mechanism 66 in a compact manner, so that an intermediate diameter expansion portion having a large diameter expansion ratio (ratio between the diameter expansion portion of the hole pile and the cross-sectional area of the shaft portion). Can be formed in the middle of the hole pile.

  The conventional diameter-expanded excavation bucket can excavate an expanded portion with an expansion rate of about 3.2 or less. However, in the diameter-expanded excavation bucket 22 of the present embodiment, a link mechanism 66 is used. Therefore, excavation of the expanded portion having a diameter expansion ratio of about 5.0 at the maximum can be performed.

  Further, since the hydraulic cylinder 70 is incorporated in the link mechanism 66, the height of the expansion / contraction bucket portion 38 can be kept low, so that the mechanical height of the diameter-excavation bucket 22 can be reduced. .

  Further, since the link member 78 serving as the support arm of the side wall plate 30 is directly operated by the hydraulic cylinder 70, there is no loss of transmission force, and mechanical efficiency can be improved.

  Although only two hydraulic cylinders 70 are shown in FIG. 9, the hydraulic cylinder 70 and the link mechanism 66 are provided on each of the four side wall plates 30. That is, the four hydraulic cylinders 70 are mounted on the expansion / contraction bucket portion 38.

  As shown in FIG. 2, the lower stabilizer part 40 as a stabilizer part is comprised by the suspension support | pillar 94 and the earth and sand collection bucket 96 as a saucer. The earth and sand collection bucket 96 is a cylindrical container having a bottom plate 100.

  As shown in FIG. 10, the lower stabilizer part 40 as a stabilizer part is provided in the lower end part of the fixed post 24 as a rotating shaft so that attachment or detachment is possible. The upper end portions of the four suspension posts 94 are joined to the lower surface of the joining member 98 that is detachably attached to the lower end portion of the fixed post 24, and spread in four directions toward the lower outer side. The lower end portion of the suspension column 94 is joined to the upper portion of the side wall of the earth and sand collection bucket 96.

  As shown in FIG. 11, the upper portion of the joining member 98 of the lower stabilizer portion 40 is a cylindrical insertion portion 170. Further, a through hole 171 of a bolt 174 is formed in the fitting portion 170.

  An insertion hole 172 of the insertion portion 170 is provided at the lower portion of the fixed post 24 as a rotation shaft. Above the insertion hole 172, the hollow portion of the square cylindrical fixing post 24 is buried so that the top of the inserted insertion portion 170 hits and stops. Further, a through hole 173 is formed in the lower portion of the fixed post 24 so as to coincide with the through hole 171 when the fitting portion 170 is completely fitted into the fitting hole 172.

  Then, as shown in the right figure of FIG. 11, the positions of the through hole 171 and the through hole 173 are aligned, the bolt 174 is passed, and the nut 175 is tightened to connect the fitting portion 170 to the fixed post 24.

  The attachment structure of the lower stabilizer portion 40 may be any structure as long as it can be easily attached and detached and can firmly fix the lower stabilizer portion 40 to the lower portion of the fixing post 24. The fixing post 24 and the fitting portion 170 are connected by a pin. May be.

  As shown in FIG. 9, the earth and sand collection bucket 96 is attached so that the opened upper surface of the earth and sand collection bucket 96 is always lower than the tip of the arm member 34.

  The outer diameter of the earth and sand collection bucket 96 is smaller than the diameter of the pile hole 20 so that a slight gap is formed between the side wall surface of the earth and sand collection bucket 96 and the hole wall of the pile hole 20.

  As shown in FIG. 10, a disk-like bottom plate 100 that serves as a lid for the earth and sand collection bucket 96 is connected to the inside of the lower part of the side wall of the earth and sand collection bucket 96 so as to be openable and closable in the direction of arrow V. ing. By this opening and closing, the excavated earth and sand loaded in the earth and sand collecting bucket 96 is discharged on the ground.

  A lock mechanism 104 for the bottom plate 100 is provided in the vicinity of the side wall facing the hinge 102 of the earth and sand recovery bucket 96. A round bar 110 is rotatably supported by an upper support 106 and a lower support 108 that are provided at the lower and upper side walls of the earth and sand collecting bucket 96 and projecting inward, and with respect to the horizontal plane of the bottom plate 100 in a covered state. Stands vertically.

  A handle 112 is provided at the upper end of the round bar 110, and a lock member 114 is provided at the lower end. The lower part of the lock member 114 has a shape having inclined surfaces 114A and 114B as shown in FIG.

  As shown in FIG. 13 when the earth and sand collection bucket 96 is viewed from above, a spring 118 is provided between the substantially central portion of the handle 112 and the bracket 120 protruding from the upper support 106, and is opposite to the arrow W. The handle 112 is urged in the direction of. At this time, since the handle 112 hits the stopper member 122 fixed to the upper surface of the upper support 106, the handle 112 does not turn further to the bracket 120 side than this position. Further, a stopper member 126 is fixed to the upper surface of the upper support 106. The stopper member 126 contacts when the handle 112 rotates in the direction of arrow W and reaches the position 112A.

An opening 124 (width d ₂ ) slightly larger than the planar outer shape (width d ₁ ) of the lock member 114 is formed in the bottom plate 100. The opening 124 is formed at a position where the handle 112 is fitted in the lock member 114 when the handle 112 is rotated in the direction of the arrow W and hits the stopper member 126.

In FIG. 13A, the length d ₃ between the corner of the lock member 114 and the other corner of the lock member 114 facing the lock member 114 is larger than the width d _{2 of the} opening 124. Therefore, the lock member 114 is hooked on the edge of the opening 124 and locked. As a result, the bottom plate 100 is kept closed.

When the handle 112 is rotated in the direction of the arrow W against the spring 118, as shown in FIG. 13B, the lock member 114 is arranged at a position (d ₂ > d ₁ ) where the lock member 114 is fitted. The lock is released.

  Then, the bottom plate 100 is rotated and opened in the direction of the arrow Y with the hinge 102 as the center of rotation by the weight of the earth and sand.

  To close the opened bottom plate 100, the bottom plate 100 is pushed up by an external force, or the diameter-excavation bucket 22 is lowered to the ground, and the bottom plate 100 is closed by its own weight.

  14, when the bottom plate 100 is pushed up, the back side of the edge portion 128 of the opening 124 comes into contact with the inclined surfaces 114A and 114B of the lock member 114 (see FIG. 14A). )) Further, the lock member 114 rotates against the spring 118 around the center of the round bar 110 by pushing up the bottom plate 100 (FIG. 14B), and finally the lock member 114 is fitted to the opening 124. When the position reaches the position (FIG. 14C), the opening 124 passes through the lock member 114 and the bottom plate 100 is closed.

  The lock member 114 that has passed through the opening 124 is returned to the same position as in FIG. 14A by the urging force of the spring 118, and the bottom plate 100 is automatically locked (FIG. 14D).

  FIG. 15 shows an overall configuration of an excavator 130 that forms an enlarged bottom portion at the bottom of the pile hole 154 in which the intermediate diameter enlarged portion 56 is formed in the pile hole 20 of FIG. 1.

  Since the configuration other than the expanded bottom excavation bucket 132 arranged at the bottom of the pile hole is substantially the same as that shown in FIG.

  The lower end portion of the kelly bar 12 is pin-connected to the connection bracket 26 on the shaft member 60 connected to the upper end portion of the fixed post 24 of the bottom-excavation bucket 132.

  The pile hole 154 includes a shaft portion 54 that has not been subjected to diameter expansion excavation and an intermediate diameter expansion portion 56 that has been excavated by the bucket 22 for diameter expansion excavation. The intermediate enlarged diameter portion 56 includes an upper inclined surface 56A, a vertical surface 56B, and a lower inclined surface 56C, and is formed at two intermediate positions of the pile hole 154.

  As shown in FIG. 16, the bottom-excavated bucket 132 includes an upper stabilizer portion 36, an expansion / contraction bucket portion 136, and a bottom lid portion 138, and is arranged in this order from the top.

  The expansion / contraction bucket portion 136 is obtained by removing the arm member 34 and the lower stabilizer portion 40 of the expansion / contraction bucket portion 38 of FIG. 2 and attaching a detachable bottom lid portion 138.

  As shown in FIG. 17, the side wall plate 30 is expanded and contracted by the same operation procedure as in FIG. 9.

  As shown in FIG. 18A, the support member 140 is detachably fixed to the lower end portion of the fixed post 24. And the bottom cover 144 is rotatably connected to the hinge 142 provided in the edge part of the supporting member 140. As shown in FIG. As shown in FIG. 19, a fitting portion 170 is provided on the upper surface of the support member 140, and the bottom lid portion 138 is detachably attached to the fixed post 24 as a rotating shaft by the same structure as the lower stabilizer 40. Yes.

  As shown in FIG. 18A, the bottom lid 144 has a conical shape that is pointed downward, and can be opened and closed in the direction of the arrow K by a hinge 142. Thereby, the excavated earth and sand loaded in the expansion / contraction bucket part 136 is discharged on the ground.

  Since the lock mechanism 104 of the bottom lid 144 is the same as that provided in the earth and sand collection bucket 96, description thereof is omitted.

  Since the hinge 142 is provided at a position about 1/4 in the diameter direction of the bottom lid 144, the distance from the lower end of the expansion / contraction bucket portion 136 to the ground surface is reduced when the bottom lid 144 is opened. be able to. Therefore, since the machine height of the bottom-excavation bucket 132 at the time of sediment discharge can be reduced, the mechanical height of the bottom-excavation bucket 132 does not increase even when the bottom cover is enlarged to facilitate the discharge of the excavation earth and sand. .

  As shown in FIG. 18B, which is a plan view of the bottom lid 144 as seen from below, the bottom lid 144 is formed with two substantially fan-shaped openings 146 at positions symmetrical to the center of the bottom lid 144. ing. A long excavation bit 148 is attached to one end of the opening 146 in the rotational direction. Further, the bottom lid 144 is provided with an opening / closing plate 150 that covers the opening 146 from the upper surface side of the bottom lid 144. ing.

  As shown in FIG. 20, the opening / closing plate 150 is opened and closed in the direction of arrow G by a hinge 152 provided in the vicinity of the edge of the opening 146 so as to face the excavation bit 148.

  The excavation bit 148 has a shape pointed downward. Therefore, when the fixed post 24 is rotated in the direction of the arrow M by the swivel device 14 via the kelly bar 12 and the bottom cover 144 is rotated together with the side wall plate 30, excavation is performed by the excavation earth and sand accumulated in the hole bottom and the excavation bit 148. The earth and sand flowed in the direction of the arrow J, whereby the excavated earth and sand are collected on the bottom lid 144.

  When the bottom-excavation bucket 132 is lifted to the ground by the crane 16 for discharging the earth and sand, the opening and closing plate 150 is closed by the dead weight of the earth and sand placed on the opening and closing plate 150, so that the earth and sand spills from the opening 146. Never happen.

  Next, the operation and effect of the diameter-excavation bucket 22 according to the embodiment of the present invention will be described.

  As shown in the construction procedure diagrams of FIGS. 21 and 22, in the present embodiment, first, the intermediate expanded portion is excavated, and finally, the expanded bottom portion is excavated. In addition, since the arm member 34 and the lower stabilizer part 40 can be attached or detached to the lower end part of the side wall board 30, the arm member 34 and the lower stabilizer part 40 are removed, the arm member which has another inclination angle, and the bottom cover part for bottom expansion excavation 138 can be easily replaced.

  First, in FIG. 21 (A), the ground pile 28 is excavated in advance with a drilling bucket for Keriba to form the hole pile 20. And the bucket 22 for diameter expansion excavation is arrange | positioned in the position which forms the intermediate diameter expansion part in the hole pile 20 filled with the stabilizing liquid L, such as bentonite which prevents collapse of a hole wall.

  Here, the upper stabilizer portion 36 provided on the upper portion of the diameter-excavation bucket 22 slides the slide member 44 to such an extent that a slight gap is left between the hole wall of the pile hole 20 and the guide member 42. 42 is adjusted, and is fixed by two bolts 48 at a position where the through hole 50 and the through hole 52 coincide with each other. Moreover, the slide amount of all the slide members 44 is equal.

  Thereby, the guide member 42 contacts the hole wall of the pile hole 20 and guides the center of the fixed post 24 connected to the shaft member 60 to the center position of the pile hole 20. Therefore, since the center of the fixed post 24 serving as the rotation axis is always at the center position of the pile hole 20 by the upper stabilizer portion 36, the roundness when the intermediate enlarged portion is excavated from the bottom to the top can be increased. .

  A lower stabilizer 40 is also provided below the arm member 34. The side wall surface of the earth and sand recovery bucket 96 of the lower stabilizer 40 contacts the hole wall of the pile hole 20 to guide the center of the fixed post 24 to the center position of the pile hole 20. Therefore, since the center of the fixed post 24 is always at the center position of the pile hole 20 by the lower stabilizer portion 40, the roundness when the intermediate diameter enlarged portion is excavated from the top to the bottom can be increased.

  Next, in FIG. 21 (B), according to the operation procedure of FIG. 9, the side wall plate 30 is expanded outward while the fixing post 24 is rotated in the direction of the arrow M by the turning device 14 via the kelly bar 12.

  At this time, the excavation bit 32 of the side wall plate 30 and the excavation bit 58 of the arm member 34 excavate the hole wall of the pile hole 20, and the intermediate diameter enlarged portion 56 is formed.

  As the excavation method of the intermediate diameter enlarged portion 56, there are a method of excavating from the top to the bottom as shown in FIG. 23 and a method of excavating from the bottom to the top as shown in FIG. Which method is used may be appropriately determined in consideration of the shape of the intermediate enlarged portion, the soil quality, the number of times of expansion / contraction.

  As shown in FIG. 23A, first, the diameter-extended excavation bucket 22 is lowered to a predetermined position by the crane 16 in a state where the diameter of the diameter-extended excavation bucket 22 is minimized.

  Next, as shown in FIG. 23 (B), while rotating the fixed post 24, the side wall plate 30, and the arm member 34, the side wall plate 30 is expanded to the position of the inclined surface 56A at the upper part of the intermediate enlarged diameter portion. Go. After this excavation is completed, the diameter-extended bucket 22 is returned to the state shown in FIG. 23A where the diameter of the enlarged-excavation bucket 22 is minimized, and the enlarged-diameter bucket 22 is lowered to the next excavation position.

  At this position, excavation similar to that shown in FIG. 23B is performed, and this procedure is repeated to gradually lower the diameter-extended excavation bucket 22 downward as shown in FIGS. 23C to 23E. Move it. And the intermediate diameter expansion part 56 is formed by the excavation of this vertical division.

  Therefore, the inclined surface 56A at the upper portion of the intermediate enlarged portion is excavated by the excavation bit 32 of the upper portion of the sidewall plate 30A, and the vertical surface 56B of the largest diameter portion of the intermediate enlarged portion 56 is provided on the vertical wall surface of the lower portion of the sidewall plate 30B. The inclined surface 56 </ b> C below the intermediate enlarged diameter portion 56 is excavated by the excavation bit 58 provided on the arm member 34.

  In FIG. 24, the intermediate diameter enlarged portion 56 is excavated from the bottom to the top by rotating the side wall plate 30 and the arm member 34 outward while rotating in substantially the same procedure as in FIG.

  In this embodiment, the side wall plate 30 and the arm member 34 are expanded at once to the position where excavation is planned. However, the enlarged-diameter excavation bucket 22 is reciprocated up and down several times over the entire length of the intermediate expanded portion 56. In addition, it may be used in combination with horizontal division excavation that increases the diameter little by little.

  The earth and sand excavated by the excavation bit 32 provided on the side wall plate 30 and the excavation bit 58 provided on the arm member 34 flows into the earth and sand recovery bucket 96 as indicated by an arrow U in FIG. At this time, the smaller the gap between the side wall surface of the earth and sand collecting bucket 96 and the hole wall of the pile hole 20, the smaller the amount of earth and sand that spills from the gap, so the outer diameter of the earth and sand collecting bucket 96 is the pile hole 20. It is preferable that the length is as close as possible to the diameter.

  When the earth and sand collection bucket 96 is filled with the excavated earth and sand that has flowed in, the crane 16 pulls up the enlarged diameter excavation bucket 22 to the ground as shown in FIG. 21C, and the bottom plate 100 is removed by the procedure shown in FIG. Open and discharge excavated sediment. Then, the operations shown in FIGS. 21A to 21C are repeated as appropriate, and the intermediate diameter enlarged portion 56 is formed at a necessary location.

  When the excavation of all the intermediate enlarged diameter portions 56 is completed, as shown in FIG. 21D, the arm member 34 and the lower stabilizer portion 40 of the enlarged diameter excavation bucket 22 are removed, and the bottom lid portion 138 is attached. The bottomed excavation bucket 132 is used, and the crane 16 is lowered to the bottom of the pile hole with the diameter of the bottomed excavation bucket 132 minimized.

  Next, as shown in FIG. 22 (E), the bottomed excavation is performed according to the operation procedure shown in FIG. 17 while rotating the fixed post 24, the side wall plate 30, and the bottom lid 144. At this time, the earth and sand excavated by the excavation bit 32 provided on the side wall plate 30 is as indicated by an arrow Z in FIG. 17C, and the excavated earth and sand accumulated at the bottom of the pile hole 154 is as shown in FIGS. It flows in the direction of arrow J and accumulates on the bottom lid 144.

  When the collected earth and sand reaches the maximum load capacity of the bottom-excavation bucket 132, the side wall plate 30 is moved inward to minimize the diameter of the bottom-excavation bucket 132, as shown in FIG. Then, the crane 16 pulls up the bottom-excavated bucket 132 to the ground, opens the bottom lid 144, and discharges the excavated soil.

  Here, the hydraulic cylinder 70 of the bottom expanding excavation bucket 132 can output a larger power during the extending operation. Further, a larger power is required for the diameter reducing operation for collecting excavated earth and sand in the center than for the diameter expanding operation of the side wall plate 30 when excavating the hole wall of the pile hole 154. Therefore, since the link mechanism 66 is a mechanism in which the side wall plate 30 is reduced in diameter when the piston rod 86 of the hydraulic cylinder 70 is extended, the hydraulic cylinder 70 can be effectively operated.

  After the earth and sand are discharged to the ground, the bottom expanding excavation bucket 132 is again lowered to the bottom of the pile hole 154 and the bottom expanding excavation is performed. And the operation | work of FIG.22 (E) and (F) is repeated, the expanded bottom part 158 is formed, and the pile hole 156 expanded in multiple steps as shown in FIG.22 (G) is constructed | assembled.

  As described above, in this embodiment, since the arm member 34 is detachably provided at the lower end portion of the side wall plate 30, the arm member suitable for the inclined surface of the lower portion of the intermediate enlarged diameter portion to be excavated is attached. By doing so, it is possible to cope with excavation of various inclined surfaces at the lower part of the intermediate enlarged diameter portion.

  In addition, since an intermediate enlarged part having an inclined surface can be formed, collapse of the bottom of the lower part of the intermediate enlarged part after excavation is prevented, and slime or the like in the hole wall stabilizing liquid is formed in the lower part of the intermediate enlarged part. It can be prevented from depositing.

  In addition, in the case of separately producing a large-diameter excavation bucket having a side wall plate shaped to match the inclined surface of the lower intermediate-diameter portion, two buckets for bottom-expanding excavation and intermediate enlarged excavation are added to one construction. However, since the arm member 34 and the lower stabilizer portion 40 are detachable, the arm member 34 and the lower stabilizer portion 40 can be detached. By attaching a detachable bottom cover 138 for expanding bottom excavation to the lower end portion of the fixed post 24, it is possible to perform excavation of both intermediate diameter expanding and bottom expanding with one diameter expanding excavation bucket.

  Moreover, since the center of the rotating fixed post 24 is always at the center position of the pile hole by the upper stabilizer portion 36 and the lower stabilizer portion 40, the roundness of the intermediate enlarged diameter portion can be increased.

  In addition, in the ordinary diameter expansion excavation bucket, the stabilizer portion is only provided on the rotating shaft located above the blade expansion portion, so that the intermediate diameter expansion portion excavation is performed while moving the diameter expansion excavation bucket from the top to the bottom. When performing, the diameter of the excavated pile hole becomes larger than the diameter of the stabilizer portion, so that the stabilizer portion above the wing expansion portion does not contact the hole wall of the pile hole. Therefore, the stabilizer part located above the wing expansion part does not fulfill the role of guiding the center of the rotating shaft to the center position of the pile hole.

  However, since the large-diameter excavation bucket 22 of the present embodiment is provided with the earth and sand collection bucket 96 of the lower stabilizer portion 40 below the arm member 34, the large-diameter excavation bucket 22 is moved from the top to the bottom. Even when excavation with an intermediate diameter is performed (FIG. 23), the lower stabilizer portion 40 below the arm member 34 always serves as a guide, thereby increasing the roundness of the intermediate diameter expansion portion.

  Moreover, since the earth and sand collection bucket 96 of the lower stabilizer section 40 can directly receive the earth and sand excavated by the side wall plate 30 and the arm member 34, the earth and sand collecting bucket 96 can collect the excavated earth and sand that has fallen and accumulated at the bottom of the pile hole. The work of repeatedly lowering the recovery bucket to the bottom of the pile hole may not be frequently performed.

  Thus, by using the bucket 22 for diameter expansion excavation of this embodiment, since an intermediate diameter expansion part can be formed in the middle of a pile hole, when a pile is built in this pile hole, an intermediate diameter expansion part Works like a screw thread in the ground, and can obtain a large vertical support force and pull-out resistance force from the surrounding ground.

  Therefore, sufficient vertical support force and pulling resistance force can be obtained even if the diameter is reduced, so that it is possible to reduce drilling soil that is a construction by-product and hole wall stabilizing liquid used during pile construction, and to reduce environmental impact. it can.

  Furthermore, since the concrete and reinforcing bar which are materials of a pile can be reduced, cost reduction and construction period shortening can be aimed at. High-strength concrete can increase the strength of the pile itself, and is therefore suitable as a material for a pile having an intermediate expanded portion and a bottom expanded portion with a high expansion ratio.

  In the present embodiment, the example in which the bottom-expanded portion 158 is excavated after the intermediate-diameter expanded portion 56 is excavated has been shown. The portion 56 may be excavated. When excavating the bottom expanded portion after excavating the intermediate diameter expanded portion, the excavated earth and sand collected at the bottom of the pile hole can be collected together last.

  Moreover, although the example which excavates the intermediate | middle enlarged diameter part 56 and the bottom expanded part 158 after excavating the ground 28 with the drilling bucket for kelly bar in advance and forming all of the hole piles 20 was shown, a hole pile is dug in steps. You may make it excavate an intermediate diameter enlarged part, advancing. Excavation of the intermediate expanded portion and the expanded bottom portion after forming all the hole piles can reduce the number of times the excavation bucket passes through the intermediate expanded portion where the excavation has been completed. It is possible to prevent collapse of the lip of the diameter portion.

  Moreover, the pile hole 20 may be excavated by the bucket 132 for bottom-excavation excavation.

  Moreover, although the example which provided the four side wall board 30 was shown, the side wall board 30 should just be comprised by two or more so that it can be divided | segmented. When there are two side wall plates 30, the expansion / contraction force is biased in two directions, making it difficult to ensure sufficient roundness, and increasing the number of side wall plates 30 complicates the structure and requires many hydraulic cylinders. Therefore, the number of side wall plates 30 is preferably four.

  Further, the excavation bits 32, 58, and 148 only need to be capable of excavating the ground, and the size, arrangement, and the like may be appropriately determined as necessary.

  Further, the hinge 102 for opening and closing the bottom plate 100 is provided inside the lower portion of the side wall of the earth and sand collecting bucket 96. However, if structurally possible, the hinge is further inserted inside like the bottom lid 144. You may provide in a position. Thereby, when the bottom plate 100 is opened, the distance from the lower end of the earth and sand collection bucket 96 to the ground surface can be reduced. Therefore, even when the large bottom plate 100 is used to facilitate discharging the excavated earth and sand. The machine height of the bucket 22 for expanding digging when discharging earth and sand does not increase.

  Moreover, the expansion / contraction bucket part 38 should just be a thing in which a lower stabilizer part, an arm part, and a bottom cover part are attached so that attachment or detachment is possible, and an wing expansion part expands / contracts, and does not need to use the link mechanism 66. .

  The lower-diameter excavation bucket 22 is provided with a lower stabilizer portion 40 at the lower side, and the machine height is increased. Therefore, the expansion / contraction bucket portions 38 and 136 with a low height, as in this embodiment, and the expansion / contraction bucket when opened. It is preferable to use a bottom lid 144 having a small distance from the lower end of the portion 136 to the ground surface.

  Also, the bucket 22 for expanded diameter excavation can be adapted to excavate various inclined surfaces at the lower portion of the intermediate enlarged portion by mounting the arm member 34 that matches the inclined surface at the lower portion of the intermediate enlarged portion to be excavated. Although it is possible, it is preferable in terms of construction and structure that the inclination angle of the inclined surface at the lower portion of the intermediate enlarged portion is about 45 degrees.

  Moreover, although the example which formed the intermediate | middle enlarged diameter part 56 in the middle two places of the pile hole 20 was shown, what is necessary is just to determine suitably arrangement | positioning and number of intermediate enlarged parts according to the vertical support performance etc. which are calculated | required by a pile. .

  The hydraulic cylinder 70 may be any device that expands and contracts a member corresponding to the piston rod 86.

  Further, the suspension column 94 is not limited as long as the earth and sand collection bucket 96 is attached to the lower end portion of the fixed post 24 so as to ensure the strength having a function as a guide, and excavated earth and sand can enter from the side. Alternatively, a cylindrical pipe standing vertically from the center of the earth and sand collection bucket 96 may be used.

  The upper stabilizer portion 36 may have any shape as long as it can guide the rotation shafts of the enlarged diameter excavation bucket 22 and the expanded bottom excavation bucket 132 to the center position of the pile hole. The upper stabilizer 36 may be omitted if excavation with roundness is possible.

  When the lower stabilizer portion 40 does not need to have a guide function, the diameter of the earth and sand collection bucket 96 may be reduced, or may be another shape such as a square or a polygon in plan view. In addition, when there is a margin in the machine height of the diameter-excavation bucket 22, the earth and sand collection bucket 96 may be a deep saucer.

  On the contrary, when the lower stabilizer 40 does not need to have the earth and sand recovery function, the upper and lower stabilizer 36 may be used, for example, without using the earth and sand collection bucket 96 as a tray.

It is the schematic which shows the excavator which concerns on embodiment of this invention. It is a perspective view which shows the bucket for diameter expansion excavation which concerns on embodiment of this invention. It is a top view which shows the upper stabilizer part which concerns on embodiment of this invention. It is AA sectional drawing of FIG. It is a front view which shows the bucket for diameter expansion excavation which concerns on embodiment of this invention. It is the front view and sectional drawing which show the arm member which concerns on embodiment of this invention. It is explanatory drawing which shows the attachment / detachment method of the arm member which concerns on embodiment of this invention. It is explanatory drawing which shows the attachment / detachment method of the arm member which concerns on embodiment of this invention. It is explanatory drawing which shows the expansion / contraction operation | movement of the bucket for diameter expansion excavation which concerns on embodiment of this invention. It is a front view which shows the lower stabilizer part which concerns on embodiment of this invention. It is explanatory drawing which shows the attachment or detachment method of the lower stabilizer part which concerns on embodiment of this invention. It is a perspective view which shows the locking member of the lower stabilizer part which concerns on embodiment of this invention. It is explanatory drawing which shows the locking mechanism of the lower stabilizer part which concerns on embodiment of this invention. It is explanatory drawing which shows the locking mechanism of the lower stabilizer part which concerns on embodiment of this invention. It is the schematic which shows the excavator which concerns on embodiment of this invention. It is a perspective view which shows the bucket for bottom expansion excavation which concerns on embodiment of this invention. It is explanatory drawing which shows the expansion / contraction operation | movement of the bucket for bottom expansion excavation which concerns on embodiment of this invention. It is the front view and top view which show the bottom cover part which concerns on embodiment of this invention. It is explanatory drawing which shows the attachment or detachment method of the bottom cover part which concerns on embodiment of this invention. It is explanatory drawing which shows the earth and sand collection | recovery method of the bucket for bottom expansion excavation which concerns on embodiment of this invention. It is explanatory drawing which shows the construction procedure of the bucket for extended diameter excavation and the bucket for extended bottom excavation which concerns on embodiment of this invention. It is explanatory drawing which shows the construction procedure of the bucket for extended diameter excavation and the bucket for extended bottom excavation which concerns on embodiment of this invention. It is explanatory drawing which shows the excavation method of the intermediate diameter expansion part which concerns on embodiment of this invention. It is explanatory drawing which shows the excavation method of the intermediate diameter expansion part which concerns on embodiment of this invention. It is the schematic which shows the conventional bottom expanded pile. It is the schematic which shows the conventional intermediate diameter enlarged pile. It is the schematic which shows the conventional division | segmentation bucket type | mold rotary excavation apparatus.

Explanation of symbols

10 Excavator 20 Pile hole (vertical hole)
22 Bucket for expanding drilling 24 Fixed post (rotating shaft)
30 Side wall plate (wing expansion part)
34 Arm member (arm part)
40 Lower stabilizer part (stabilizer part)
56 Middle diameter expansion part 56C Inclined surface 96 Sediment collection bucket

Claims (3)

Provided on a rotating shaft that is suspended and rotated by the excavator body, and has a lower portion that forms a cylindrical outer peripheral surface centering on the rotating shaft, and an upper portion that forms an inclined surface that extends from the upper end of the lower portion toward the center of the vertical hole. And expanding and contracting so as to move in parallel in the horizontal direction, excavating the hole wall of the vertical hole, and forming an intermediate expanded portion in the middle of the vertical hole, and
The diameter of the cylinder formed by the bottom of拡翼portion detachably provided in plurality in the lower end portion of the拡翼portion so as to intersect when the minimum, of the vertical hole at the bottom of the intermediate diameter portion An arm portion that forms an inclined surface facing downward in the center;
A diameter expansion excavation bucket comprising: A stabilizer portion that is detachably provided at a lower end portion of the rotation shaft, and that contacts a hole wall of the vertical hole and guides the center of the rotation shaft to a center position of the vertical hole;
2. The diameter-extended excavation bucket according to claim 1, wherein the stabilizer portion is located below the arm portion.   The diameter expansion excavation bucket according to claim 2, wherein the stabilizer portion is a tray.

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