JP6074472B2 - Ground excavation method and excavator - Google Patents

Description

  The present invention relates to a ground excavation method and an excavation apparatus. More specifically, the present invention relates to an improvement in excavation technology when a pile body is constructed in the ground.

  The CFA (Continuous Flight Auger) method is proposed as a method for constructing piles and column walls (underground walls) in the ground. This method is, for example, drilling to a predetermined depth with a large-diameter auger (pile drilling machine), discharging earth and sand, pouring concrete and mortar from the tip while pulling up this auger, and then placing the core It is intended to construct cast-in-place piles and column wall walls by inserting reinforcing bars and steel molds into concrete and mortar, and it is relatively easy to construct pile bodies such as piles and column wall walls by site construction. There is an advantage. In this CFA method, while preventing the hole wall from collapsing during drilling, the soil and sand are replaced with concrete or mortar in the drilling hole to construct a pile or column wall, and the discharged sediment is discarded.

  In such a CFA method, conventionally, the diameter of the excavating rod is gradually increased (gradually decreased) in order to reduce the amount of soil removal (see, for example, Patent Documents 1 and 2), or a spiral to enable excavation even on hard ground. A device in which the spiral pitch (axial pitch) of the blades is changed (see, for example, Patent Document 3) is disclosed.

Japanese Examined Patent Publication No. 7-68838 Japanese Patent No. 2631303 International Publication No. 95/12050

  However, in the conventional CFA method, the support performance of the pile body after construction may not be sufficient.

  Then, an object of this invention is to provide the ground excavation method and excavation apparatus which improved the support performance of the pile body in excavation ground.

  In order to solve this problem, the present inventor has made various studies. First, in the CFA method, when the hardened material such as concrete or mortar is poured into the drilling hole and placed, the vicinity of the tip of the drilling rod is closed (there is almost no gap with the ground). The excavation rod is pulled up to form a space. However, when the excavation rod is pulled up, the space between the excavation rod and the ground becomes negative pressure, so that the ground loosens or the hole wall collapses, resulting in a weak support performance. is there. In addition to this, considering the factors that reduce the support performance, the CFA method basically has little soil removal, but if the excavation rod is rotated excessively while the ground is being dug, the amount of soil will increase and the surrounding soil will increase. It was thought to loosen. The present inventor, who has made further studies focusing on such points, has come to obtain new knowledge that leads to the solution of such problems.

  The present invention is based on such knowledge, and in a method of excavating the ground using an excavation rod provided with a screw on the outer periphery, as the excavation rod, part or all of the gap between the blades constituting the screw. A rod comprising: at least one closing member that shields, and an expansion excavation member that is disposed closer to the distal end side of the excavation rod than the closure member and excavates a diameter-expanded portion larger than the excavation diameter of the ground by the screw. And using the excavating rod to rotate the excavating rod in at least a part of the excavation step and the step of extracting the excavating rod from the excavation hole, and transport the earth and sand conveyed to the rear end side of the rod by a screw. Part of the earth and sand is kneaded to the hole wall of the excavation hole. Parts wherein the excavating enlarged diameter portion by expanding the drilling member relative to the batter Tagged hole wall.

  As a general action during ground excavation, when the excavating rod is rotated in the ground, the sand is guided upward by the screw and is discharged, and if the amount of soil is increased, the surrounding ground loosens. Is likely to occur. In this respect, according to the excavation method of the present invention, the closing member formed between the blades constituting the screw suppresses the earth and sand from being discharged along the screw. The earth and sand whose earth removal has been suppressed is pressed (kneaded) to the outside (wall surface of the excavation hole) when the excavation rod rotates, thereby improving the shear strength of the peripheral ground and suppressing loosening of the peripheral ground. In the present invention, when the excavation rod is pulled out from the excavation hole, the enlarged excavation member excavates a part of the surrounding ground whose strength has been improved in this way, and, for example, a spiral diameter-expanded portion is formed in the hole wall. Then, when the hardening material cast in the excavation hole is hardened, a node portion corresponding to the shape of the enlarged diameter portion is built on the outer periphery of the pile body. Such a node increases the frictional force near the peripheral surface of the pile body with respect to the surrounding ground. Therefore, the support performance with respect to the said pile body in the said excavation ground will improve.

  Moreover, in the excavation method according to the present invention, the enlarged excavation member is always installed so as to excavate an enlarged diameter portion having a diameter larger than the excavation diameter of the ground by the screw. According to this, in the drawing process of the excavation rod, the enlarged diameter portion can be excavated in the hole wall by the enlarged excavation member. Moreover, even if the enlarged excavation member disturbs the surrounding ground in the excavation process using the excavation rod, the earth and sand are kneaded and pressed against the part by the action of the blocking member, and the shear strength higher than the natural ground is exhibited. The

  In the excavation method according to the present invention, the excavation rod is extracted while being continuously rotated in the extraction process. By continuously rotating the excavation rod in this way, the enlarged diameter excavating member can excavate the diameter-expanded portion continuous with the hole wall of the excavation hole in a spiral shape.

  Alternatively, in the pulling process, the excavating rod may be pulled out while rotating discontinuously. As the excavation rod rotates intermittently, a discontinuous expanded portion is excavated in the hole wall of the excavation hole.

  In the ground excavation method, it is also preferable to pull out the excavation rod while rotating it forward. Generally, in the CFA method, when the excavated ground remains in the excavation hole, the quality of the pile body is significantly deteriorated. For this reason, it is necessary to place the excavated earth and sand between the screws and pull them up as they are without rotating the excavation rod. On the other hand, if the excavation rod without a closing member as in the present invention is rotated and pulled up from the excavation hole, the surrounding ground is drawn and collapse is caused. As a result, the excavated volume cannot be grasped. There is a risk that the balance with the injection amount of the hardening material to be broken will be lost, and the quality of the pile body will deteriorate. As a means to prevent this, it is conceivable to install a valve-like member on the spiral that opens during excavation but prevents sediment from falling when it is pulled out, but the valve-like member acts correctly during construction. Since it is difficult to check whether or not the pile material quality remains a problem. In this regard, according to the present invention, the earth and sand on the screw can be prevented from dropping to the hole bottom without adding a special mechanism as described above.

  Alternatively, in the ground excavation method, it is also preferable to pull out the excavation rod without rotation. According to the present invention, at the time of excavation, it is possible to suppress the earth removal accompanying the rotation by the closing plate, and it is possible to further reduce the amount of earth removal by stopping the rotation at the time of pulling. Further, in the case of a design that does not require a large frictional resistance, it is possible to reduce the amount of the hardened material to be input by making no rotation without constructing an enlarged diameter portion by rotation.

  It is also preferable to excavate the ground using an excavation rod having two or more blocking members. Excavation can be further suppressed by excavating the ground using such excavation rods. In addition, this makes it possible to further knead earth and sand to the hole wall of the excavation hole when the excavation rod rotates.

  Furthermore, in the ground excavation method according to the present invention, it is also preferable to inject a hardening material into the excavation hole while lifting the excavation rod from the excavation hole. For example, in the case of dry digging (excavation without using drilling water), such a method is preferable from the viewpoint of suppressing collapse of the hole wall.

  In the ground excavation apparatus having an excavation rod having a screw on the outer periphery, the excavation rod is at least one member that blocks a part or all of the gap between the blades constituting the screw. And when the excavation rod rotates in at least a part of the excavation step using the excavation rod and the step of extracting the excavation rod from the excavation hole, the conveying action of earth and sand conveyed to the rod rear end side by the screw A blocking member that prevents a portion of the earth and sand from being kneaded to the hole wall of the excavation hole, and a diameter-enlarged portion that is disposed closer to the distal end side of the excavation rod than the blocking member and has a diameter larger than the excavation diameter of the ground by the screw And an expanded excavation member for excavating the mine.

  In the ground excavation apparatus according to the present invention, the expansion excavation member is always installed so as to excavate an enlarged diameter portion having a diameter larger than the excavation diameter of the ground by the screw.

  In such excavation apparatus, it is preferable that the excavation rod includes two or more closing members.

  In such excavation apparatus, the closing member is preferably plate-shaped. Since such a drilling device has a relatively simple configuration, it is advantageous in terms of cost and maintenance.

  Moreover, it is preferable that the excavator includes a nozzle for ejecting the hardened material injected into the excavation hole at the tip of the excavation rod.

  ADVANTAGE OF THE INVENTION According to this invention, the support performance of the pile body in excavation ground can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows an example of the excavation rod in embodiment of this invention, (A) Passing area | region of an obstruction board, (B) Plan view below a bb line, (C) Longitudinal sectional view, (D) Blade of screw Shows the passing area. (I) (a) front view of the excavation rod and (b) bottom view, (II) to (V) are diagrams sequentially illustrating steps until excavation to the hole bottom by the excavation rod, (a) of (IV) ) Is a front view of the excavating rod, and (b) is a plan view. (VI)-(X) It is a figure which shows the process of leveling a hole bottom with a drilling rod, drawing out discharging a hardening material, and inserting the core material of a pile body in a drilling hole in order. It is the schematic which shows the excavation hole excavated so that a hole bottom may become a reverse saddle-shaped convex shape. (A) It is a table | surface which shows the relationship between the tip load of a straight pile by a conventional excavation method, and a subsidence degree, and (B) is a figure which shows a straight pile. (A) The table | surface which shows the relationship between the tip load of a pile by the excavation method concerning this invention, and a subsidence degree, (B) It is a figure which shows the pile by which the spiral node was built. It is a graph which shows the relationship between the tip load of a pile by the conventional excavation method and the excavation method concerning this invention, and a settlement degree.

  Hereinafter, the configuration of the present invention will be described in detail based on an example of an embodiment shown in the drawings.

  1 to 4 show an embodiment of a ground G excavation method and excavator according to the present invention. In this embodiment, the ground G is excavated using the excavation rod 1 shown below, and the pile body (a pile, a column wall, etc.) 11 is constructed | assembled.

  In FIG. 1, reference numeral 1 denotes an excavation rod that excavates the ground G by being rotationally driven by an auger motor (not shown). The excavation rod 1 according to the present embodiment includes a screw 2, a closing plate 3, an expansion claw 4, an excavation bit 5, and the like. A spiral blade 2a is attached to the peripheral surface of the excavation rod 1, and an excavation bit 5 is provided at the lower end. In the present embodiment, when viewed from above the ground G, the case where the excavation rod 1 having the right-handed screw 2 rotates clockwise is referred to as “forward rotation”. When the excavation rod 1 rotates forward, the blades 2a rotate forward together to obtain a propulsive force, and the excavation rod 1 excavates the ground G.

  The excavation rod 1 has a hollow structure, for example, by a steel pipe shaft portion 6, and also serves as a pipe for passing a liquid or the like. A nozzle 7 for discharging the hardened material 10 is formed at the tip of the excavation rod 1 of the present embodiment (see FIG. 1 and the like). Further, a joint 8 for joining another excavation rod through, for example, an insertion pin (not shown) is formed at the upper end of the steel pipe shaft portion 6 (see FIG. 2 (IV)). In addition, when the excavation rod 1 excavates in advance, air, water, drilling fluid, or the like is ejected as necessary. In this embodiment, so-called anhydrous drilling is performed in which drilling is performed without using drilling fluid (drilling water). To do.

The screw 2 is formed by the blade | wing 2a formed in the outer periphery of the steel pipe axial part 6 helically (refer FIG. 1 etc.). The excavation rod 1 used in the present embodiment has a constant spacing (spiral pitch) between the blade 2a and the blade 2a formed in a right-handed shape (see FIG. 1 and the like). Furthermore, the excavation rod 1 used in the present embodiment is such that the outer diameter of the spirally formed blade 2a is a constant size (r ₁ ) (see FIG. 1).

  Further, it is preferable that the blades have a double spiral structure in a predetermined range of the screw 2 on the distal end side of the excavation rod 1. According to the screw 2 having a double spiral structure, during excavation (particularly at the start of excavation), the excavation rod 1 is easily bent without bending. In this embodiment, double spiral blades 2c having the same pitch as the blades 2a are formed for a half circumference from the tip of the excavation rod 1 (see FIG. 1 and the like).

The closing plate 3 is a member that blocks part or all of the gap between the blades 2 a and 2 a constituting the screw 2. For example, in the present embodiment, the closing plate 3 made of a plate-like member having a flat surface is provided only at one position in the middle of the screw 2 (see FIG. 1). The installation position of the closing plate 3 is not particularly limited, but when the rod diameter of the excavation rod 1 is D (D = 2r ₁ ), it is disposed within the range of 0 to 6D from the tip of the excavation rod 1. It is preferable that it is disposed within the range of 2D to 4D from the tip (see Example 2 described later). The reason for this is outlined as follows. That is, when excavation by the excavation apparatus of this embodiment is performed, when excavating a hard layer (support layer) in the ground G, it may be difficult to penetrate the excavation rod 1 due to the influence of the closing plate 3. Therefore, it is desirable to avoid excessively penetrating the blocking plate 3 into the support layer of the ground G, and a suitable installation position of the blocking plate 3 from this viewpoint is within a range of 2D to 4D from the tip. This is effective when the tip support force is designed to be increased by incorporating the vicinity of the tip of the excavation rod 1 into a hard layer (support layer) in the ground G.

In the present embodiment, the outer diameter r ₂ of the circular locus of the outer edge of the closing plate 3 during rotation of the excavating rod 1 is made smaller than the outer diameter r ₁ of the blade 2a (see FIG. 1). In this way, when a part of the gap between the blade 2a and the blade 2a is blocked (semi-closed state), the soil is discharged along the screw 2 outside the outer edge of the blocking plate 3. A bottleneck (a gap between the blocking plate 3 and the hole wall 20a of the excavation hole 20) 9 through which a part of the earth and sand can pass is formed (see a two-dot chain line in FIG. 1). In this embodiment, the case where the gap 9 is rectangular is illustrated, but this is only an example. For example, a trapezoidal blocking plate 3 having a longer lower side may be adopted, and the gap 9 may be widened upward from below. Alternatively, the closing plate 3 having the outer diameter r ₂ equal to the outer diameter r ₁ of the blade 2 a may be employed to eliminate the gap 9 (closed state).

The expansion claw 4 is disposed outside the excavation bit 5 disposed at the tip of the excavation rod 1 and functions as an expansion excavation member that excavates a diameter larger than the excavation diameter of the ground G by the screw 2. The expansion claw 4 of the present embodiment is a cylinder that utilizes a special mechanism (for example, a mechanism that causes the expansion claw 4 that is accommodated by the resistance of the ground (earth and sand) by reversing the excavating rod 1 to protrude), or hydraulic pressure. A mechanism that operates an actuator such as a mechanism to project the enlarged claw 4 that is mechanically housed), and it is not necessary to confirm the opening and closing of the claw. As the excavation rod 1 rotates, a groove having a diameter larger than the outer diameter r ₁ of the blade 2 a of the screw 2 is formed in the hole wall 20 a of the excavation hole 20.

  Furthermore, it is preferable that the expansion claw 4 attached to the tip position of the double spiral portion is disposed in the vicinity of the nozzle 7 that discharges the curing material 10. The expansion claw 4 of the present embodiment is installed only at the outer peripheral portion of the tip of the blade 2a that is a continuous spiral (one that is not the double spiral blade 2c). In this way, by installing the expansion claw 4 in the blade 2a in the vicinity of the nozzle 7 and in front of the nozzle 7 at the time of excavation rotation, the hardening material 10 is filled while pulling out the excavation rod 1 with rotation. In doing so, the hardened material 10 is filled immediately after excavating the surrounding ground G, so that it is possible to prevent the ground G from collapsing and to build a pile body with high strength and shape.

  Moreover, since the volume of the groove part to be built becomes small compared with the case where there are a plurality of enlarged claws 4 when the enlarged claws 4 are installed at one place as described above, the amount of the hardening material 10 per filling time Since the setting range of the filling speed can be used from a small area to a large area, it becomes easy to control at the time of construction, and it becomes easy to perform construction according to the situation.

  Further, when the node 12 is constructed by injecting the curing material 10 into the groove and curing it, when the node 12 is constructed at a predetermined pitch, The construction of the ground G is complicated because it is necessary to set the extraction speed of the excavation rod 1 faster in order to construct a double or multiple spirals so that the trajectories of the spirals do not overlap. In the case of ground that is soft and hard, the construction machine may be difficult to control. In this respect, according to the present embodiment in which the attachment position and the number of the enlarged claws 4 are in a preferable form, it is possible to avoid these problems and to build the pile body 11 with higher quality.

  The shape of the excavation rod 1 may be such that the bottom 20b of the excavation hole 20 is flat or excavated so that the hole bottom 20b is uneven. For example, when excavating so that the bottom 20b of the excavation hole 20 has an inverted saddle shape (a dome shape in which the center rises upward) and the bottom surface of the pile body 11 is similarly an inverted saddle shape, the deformation mechanism ( The support performance of the pile body 11 can be further improved, for example, the shape of the portion supporting the pile tip is changed, and the stress sharing region is expanded. Alternatively, although not particularly illustrated, the bottom of the pile body 11 is, for example, an inverted triangular pyramid that is inclined from the pile shaft center side to the outer peripheral side, so that the vicinity of the center portion of the pile body 11 is convex downward. It can also be formed. By adopting such a shape, when an axial force is applied to the pile body 11, the action in the center direction (compression direction) becomes more conspicuous in the action of the stress degree at the tip of the pile body, so the tensile strength is compressed. This is particularly preferable when the pile body 11 is constructed using the hardener 10 which is generally smaller than the strength.

  As described above, when the hole bottom 20b is made uneven, a specially shaped or arrayed excavation bit (for example, a plurality of excavation bits arranged closer to the front end side in the rotation axis direction as the one closer to the outer periphery) is attached. Although it is possible to use, the enlarged claw 4 protrudes further to the tip side than the tip 2b of the screw 2 (for example, obliquely on the tip side), and the hole bottom 20b of the excavation hole 20 is further closer to the radially outer portion. It is also preferable to be able to form a deep bottom (see FIG. 2 etc.). When excavating using such an excavating rod 1, the bottom 20 b of the excavation hole 20 is formed in an inverted saddle shape (dome shape) or a shape similar to this, and the bottom surface of the pile body 11 has the same shape. Can do.

  Then, a mode that the ground G is excavated using the above-mentioned excavation rod 1 is shown (refer FIG. 2, FIG. 3).

  First, the excavating rod 1 is rotated forward by an auger motor to excavate the ground G from the ground surface (see FIGS. 2 (I) to (III)). At this time, a spiral groove is formed in the hole wall 20a of the excavation hole 20 by the expanding claw 4 rotating together with the excavation bit 5 (see FIGS. 2 (III) and (IV)). When the excavating rod 1 has been excavated to a predetermined depth, another excavating rod 1 is added through the joint 8 to excavate further deeply (see FIGS. 2 (IV) and 2 (V)).

Here, when the excavation rod 1 is excavated, the expansion claw 4 excavates the ground G in a range larger than the outer diameter r ₁ of the blade 2a, and a part of the hole wall 20a of the excavation hole 20 is lost in a node shape. The state is assumed to be a state (hereinafter, the missing portion is also referred to as a missing portion, which is indicated by reference numeral 22 in the figure). However, when the excavation rod 1 further advances, a part of the earth and sand discharged along the screw 2 is pushed out by the closing plate 3 and kneaded to the hole wall 20a. It is kneaded, and it will be in the state where the earth and sand were replenished in the defect | deletion part 22 (refer FIG. 2 (III), (IV)).

  In addition, in FIG. 2 (V), since the horizontal arrow is described only in the vicinity of the blocking plate 3, it looks as if the earth and sand are kneaded to the hole wall 20a only in the vicinity of the blocking plate 3. Actually, due to the effect of soil removal suppression by the blocking plate 3, soil kneading action can also occur below the blocking plate 3 (between the closing plate 3 and the tip 2 b of the screw 2). In the figure, the hole wall 20a that has been subjected to (or possibly received) the kneading action is shown with gradation.

  When the tip of the excavation rod 1 reaches a predetermined depth, the excavation rod 1 is rotated at least once (idling) while maintaining the depth constant. As a result, the tip of the excavation rod 1 (excavation bit 5 and the like) is smoothed so that the hole bottom 20b of the excavation hole 20 is averaged in the circumferential direction. It becomes a state which can be made to act more uniformly with respect to the whole hole bottom 20b (refer FIG.2 (V)).

Further, when the excavating rod 1 is rotated (idled) at a predetermined depth of the ground G, the enlarged claw 4 forms an annular enlarged portion 21 having a diameter larger than the outer diameter r ₁ of the blade 2a of the screw 2. (Refer to FIG. 2 (V)). In the present embodiment, such an enlarged diameter portion 21 is formed in the vicinity of the hole bottom 20b, and the hardening material 10 is injected into the enlarged diameter portion 21 to be cured. In such a case, the hardened portion can function as a part of a node (indicated by reference numeral 12 in the figure) that increases the frictional force (circumferential frictional force) between the pile body 11 and the hole wall 20a. Moreover, by forming the enlarged diameter part 21, the bottom area of the pile body 11 can be increased and the support area | region by the ground G can be increased.

  For example, it is also preferable that the lifting height per rotation of the excavating rod 1 near the hole bottom 20b is smaller than the vertical height of the expanding claws 4. In such a case, the enlarged diameter portion 21 having a height (thickness) larger than the vertical height (thickness) of the expansion claw 4 can be formed near the hole bottom 20 b of the excavation hole 20.

  Furthermore, when the excavation rod 1 is rotated (idling) while maintaining the predetermined depth as described above, a part of the earth and sand in the excavation hole 20 is discharged along the screw 2 and a space for placing the hardening material 10 is placed. Is formed. At this time, if the excavation rod 1 is rotated excessively during excavation, the amount of soil removal increases, and the surrounding ground G such as the hole wall 20a of the excavation hole 20 may be loosened. In the present embodiment, it is possible to suppress the loosening of the ground G. That is, in this embodiment, a part of the earth and sand discharged along the screw 2 is pushed outward by the closing plate 3 and kneaded to the hole wall 20a (and the defect 22) (see FIG. 2 (V)). ). At this time, although depending on various factors such as the nature of the earth and sand, the installation mode of the blocking plate 3, the size of the gap 9, the rotation speed of the excavation rod 1, the earth and sand in the excavation rod 1 of the present embodiment is more than the blocking plate 3. It is almost suppressed that it is discharged to the top.

  When the excavation rod 1 is rotated (idled) at a predetermined depth of the ground G to level the hole bottom 20b, the process proceeds to a step of extracting the excavation rod 1. In this extraction step, the excavation rod 1 can be extracted while discharging the curing material 10 from the nozzle 7. When excavating using the drilling water as described above, it is preferable to pull out the excavating rod 1 while discharging the hardening material 10 from the viewpoint of further suppressing the collapse of the hole wall 20a. In this embodiment, the nozzle 7 is opened, the curing material 10 is discharged, and the excavation rod 1 is pulled out while filling the space (see FIG. 3 (VII) and the like). In addition, if the hardening | curing material 10 is illustrated, hardening bodies (hydraulic material), such as cement milk, ready-mixed concrete, and mortar, can be mentioned.

  Moreover, in this embodiment, in the extraction process of the excavation rod 1, the excavation rod 1 is extracted while being rotated forward. When the excavating rod 1 is pulled out while rotating in the forward direction in this way, the excavating rod 1 is pulled up while applying a force to lift the earth and sand on the screw 2 in the direction of soil removal. Therefore, the excavation rod 1 can be pulled out without adding earth and sand on the screw 2 to the hole bottom 20b without adding another mechanism.

  Further, when the excavating rod 1 is pulled out while rotating in the forward direction in this way, the expanding claw 4 digs a spiral groove in the hole wall 20a. The hardened material 10 discharged from the nozzle 7 enters the groove portion and hardens in this state, thereby building a spiral node portion 12 around the pile body 11 (see FIG. 3 (VIII) and the like). The node portion 12 may take various forms depending on the shape of the enlarged claw 4. For example, in this embodiment, the node portion 12 such as a comb-like protrusion having a substantially rectangular cross section can be constructed.

  When the excavation rod 1 is pulled out from the excavation hole 20, a core material (for example, a core material such as a reinforcing bar, steel pipe, ready-made pile) 13 of the pile body 11 is inserted into the excavation hole 20 (see FIG. 3 (IX)). When the hardening material 10 is hardened after the insertion, the pile body 11 is formed in the excavation hole 20 (see FIG. 3 (X)). Note that a part of FIG. 3 (IX) and (FIG. 3 (X) and FIG. 4 show a cross section instead of the outer periphery of the hardening material 10.

  According to the excavation method of the present embodiment described above, the tip (that is, the bottom surface of the excavation hole 20) is averaged in the circumferential direction by rotating (idling) the excavation rod 1 at the hole bottom 20b of the excavation hole 20. Can be leveled. Further, when the excavating rod 1 is rotated in a state where the depth is kept constant, a part of the earth and sand is discharged by the action of the screw 2, but at this time, the closing plate 3 suppresses the earth discharge in this embodiment. Sediment can be prevented from being discharged excessively.

  The above will be described in comparison with the conventional method. In the case of the conventional method, if the excavation rod is idled at the bottom of the excavation hole, the amount of soil removal may increase and the surrounding ground G may be loosened. For this reason, conventionally, it is not actually performed to rotate (spin) the excavating rod while maintaining the height (depth). On the other hand, in this embodiment, since excessive discharge of earth and sand can be suppressed by the action of the closing plate 3, even if the excavation rod 1 is rotated (idling) at the hole bottom 20b, the surrounding ground G Can be suppressed. By such an action, according to the excavation method of the present embodiment, the hole bottom 20b can be leveled so that the bottom surface of the excavation hole 20 is more averaged in the circumferential direction while suppressing the looseness of the ground G. . When the hole bottom 20b is processed so as to be uniform in this way, there is an effect of making it difficult to cause partial breakage in the tip ground G of the pile body 11, and as a result, the supporting force performance of the tip portion of the pile body 11 is improved. be able to. Moreover, if the hole bottom 20b is leveled, the measurement standard of the depth of the excavation hole 20 will become clear, and there also exists an advantage that it is easy to obtain a more accurate numerical value.

  Further, in the present embodiment, the closing plate 3 formed between the blade 2a and the blade 2a as described above prevents the earth and sand from being discharged along the screw 2 when the excavation rod 1 rotates. At the same time, a part thereof is kneaded to the hole wall 20 a (and the defect 22) of the excavation hole 20. For example, even when the excavation rod 1 is excavated, even if it is excavated (disturbed) by the expanding claws 4 and a part of the hole wall 20a is loosened, earth and sand are put on the loose portion by the kneading action of the closing plate 3. The ground G once loosened can be strengthened, the shear strength of the surrounding ground can be improved, and a ground for excavating the groove in the hole wall 20a can be created. In this way, kneading the earth and sand to the hole wall 20a and excavating a groove in the hole wall 20a to build a desired node 12 around the pile body 11 is a circumferential friction of the pile body 11 against the ground G. This is preferable in that the force can be increased. Such an action synergistically suppresses the loosening of the surrounding ground G. In addition, according to the present embodiment, loosening of the ground G at the distal end portion of the excavation rod 1 is suppressed by the kneading action of the closing plate 3 described above than in the case of other methods.

  In the excavation process, there may be a case where there is no constant correlation between the excavation speed and the rotation speed of the excavation rod 1. Even in such a case, according to the excavation method of the present embodiment, as a result of the blocking plate 3 suppressing the soil removal, the bottom 20b of the excavation hole 20 is leveled as in the case where there is a certain correlation. Is possible. To explain this point, for example, in the case of the conventional method, in order to suppress the loosening of the ground G, it is necessary to perform a control in which the excavation speed and the rotation speed have a certain correlation. Although it was difficult, in the excavation method of the present embodiment, since the soil removal is suppressed by a specific configuration, such control for suppressing loosening of the ground G is not essential. It can be said.

  The above-described embodiment is an example of a preferred embodiment of the present invention, but is not limited thereto, and various modifications can be made without departing from the scope of the present invention. For example, in the embodiment described above, the excavation rod 1 in which the distance (spiral pitch) between the blades 2a and 2a is constant and the outer diameter of the blades 2a is constant is used. The excavation rod 1 is not limited to this. In addition, the excavation rod 1 having a form in which the spiral pitch is not constant or the excavation rod 1 having a form in which the outer diameter of the spiral blade 2a is not constant is applied. In addition, it is possible to achieve the same operational effects as the above-described embodiment. Needless to say, any of the excavating rods 1 described in the present specification can be applied to the present invention as long as the same operational effects as the above-described embodiment can be obtained.

  Moreover, in embodiment mentioned above, although the screw 2 comprised by the continuous spiral blade | wing 2a was illustrated, this is only a suitable example. As another form, the blade | wing 2a may become the discontinuous shape in which one part interrupted above the lower end of the obstruction board 3, for example. However, even if the blades 2a have a discontinuous shape as described above, it is preferable that the blades 2a have a continuous shape below the lower end of the closing plate 3.

  Further, in the above-described embodiment, the form in which the excavation rod 1 is extracted while being continuously rotated in the extraction process is illustrated, but unlike this, the excavation rod 1 is extracted while being discontinuously rotated. It may be. As the excavation rod 1 rotates intermittently in this manner, a discontinuous enlarged diameter portion 21 is excavated in the hole wall 20a of the excavation hole 20. Therefore, according to this, it is possible to construct a pile body in which a plurality of nodes that are spiral but discontinuous are built. By constructing such a node portion, a large resistance against the ground G can be realized around the excavation rod 1.

  In the above-described embodiment, the fixed expansion claw 4 is provided as the expansion excavation member. For example, the expansion claw that can be opened and closed between the expansion position opened in the radial direction and the retracted position accommodated therein. Can also be adopted. If an openable / closable expansion claw is employed and the claw is retracted when the excavation rod 1 is excavated, the amount of disturbing the ground G (hole wall 20a) is small, and the excavation resistance is also small.

  In the above-described embodiment, the excavation rod 1 is extracted while being rotated forward in the extraction process. However, the excavation rod 1 can be extracted from the excavation hole 2 without rotation. In such a case, a linear groove portion is excavated in the hole wall 20a by the expanding claws 4, and the linear node portion 12 is similarly constructed in the pile body 11.

  Moreover, although the suitable form example of the obstruction | occlusion board 3 was demonstrated in embodiment mentioned above, this is only an example and can employ | adopt the obstruction | occlusion board 3 of a various aspect other than this. For example, a shape other than a rectangle may be employed as the closing plate 3. Alternatively, not only a flat plate shape but also a closed plate 3 having a curved surface can be employed. Further, when a plurality of closing plates 3 are provided, ones having different sizes and shapes can be arranged at different heights and different circumferential positions. Alternatively, the kneading action can be adjusted by adjusting the inclination angles of the excavation rod 1 with respect to the rotation direction to different angles.

  A plurality of closing plates 3 may be provided. If the ground G is excavated using the excavation rod 1 provided with two or more closing plates 3, soil removal during excavation can be further suppressed. In such a case, earth and sand can be further kneaded to the hole wall 20a of the excavation hole 20 when the excavation rod 1 rotates. When a plurality of blocking plates 3 are provided, the same shape of the blocking plates 3 may be used, or the shapes of the respective blocking plates 3 may be made different from each other so as to suppress the discharge of soil and the kneading action of earth and sand. May be different. When a plurality of closing plates 3 are provided, the height (depth) of each closing plate 3 can be varied, and the circumferential arrangement of each closing plate 3 (a timepiece as viewed along the rotation axis) The position of the surroundings can also be varied and can be appropriately arranged.

  In the above-described embodiment, the hardened material 10 is discharged while filling the excavation hole 20 while pulling the excavating rod 1 in the pulling process (see FIG. 2 (IV)), but after the excavating rod 1 is pulled out. The curing material 10 may be discharged. In such a case, the drawing process of the excavating rod 1 and the placing process of the hardened material 10 are separated. As a specific example, a mode in which mud water or the like is filled in the excavation hole 20 and cement milk or the like is injected and replaced with a pipe or the like is also included in the separated drawing process and placing process here. .

  A test for comparing the degree of pile settlement in the conventional excavation method (conventional construction method) and the excavation method according to the present invention (the present application) was conducted.

FIG. 5 shows the results of the conventional method (pile head load and pile head settlement of straight piles). In addition, FIG. 6 shows the results of the present technology (pile head load and pile head subsidence graph of a pile with a helical node built. FIG. 7 shows the pile head in the conventional method and the present technology. The graph of load-pile head subsidence is shown.
δo: Settling amount of pile head in loading test (mm)
D: Diameter of pile for which load test was performed (mm)
D ': outer diameter of the node (mm)
Po: Load acting on the pile head (axial force) (kN)
It is.

  From this test, it was found that the technique of the present application can suppress the degree of settlement of the pile with respect to the pile head load than the conventional method. Thereby, according to this application technique, it was confirmed that the support performance of a pile can be improved rather than before.

  The present invention is suitable when applied to a pile body such as a pile or a column wall (underground wall) in the ground.

DESCRIPTION OF SYMBOLS 1 ... Excavation rod, 2 ... Screw, 2a ... Blade | wing, 2b ... (Screw | screw) tip, 3 ... Closure board (occlusion member), 4 ... Expansion claw (expansion excavation member), 10 ... Hardening material, 11 ... Pile body, DESCRIPTION OF SYMBOLS 12 ... Node part, 20 ... Drilling hole, 20b ... Hole bottom, 21 ... Diameter expansion part, G ... Ground

Claims (5)

In the method of excavating the ground using a drill rod with a screw on the outer periphery,
As the drilling rod,
At least one blocking member that blocks part or all of the gap between the blades constituting the screw; and
An expansion excavation member that is disposed closer to the distal end side of the excavation rod than the closing member and excavates an enlarged diameter portion having a diameter larger than the excavation diameter of the ground by the screw;
Using a rod with
The blocking member is configured to rotate the excavation rod in at least a part of the excavation step using the excavation rod and the step of pulling out the excavation rod from the excavation hole and transport the earth and sand conveyed to the rod rear end side by the screw And kneading a part of the earth and sand to the hole wall of the excavation hole,
In the step of pulling out the excavation rod, the excavation rod is pulled out while rotating continuously or discontinuously, and the enlarged excavation member is applied to the hole wall where a part of the earth and sand is kneaded by the action of the closing member. A ground excavation method for excavating a continuous or discontinuous spiral expanded portion.   2. The ground excavation method according to claim 1, wherein the expansion excavation member is always installed to excavate a diameter-expanded portion having a diameter larger than a diameter of excavation of the ground by the screw. Wherein during rotation of the drill rod pulling the drill rod while the forward rotation, excavation method of the ground according to claim 1 or 2. The ground excavation method according to any one of claims 1 to 3 , wherein the ground is excavated using the excavation rod including two or more of the blocking members. The ground excavation method according to any one of claims 1 to 4 , wherein a hardener is injected into the excavation hole while the excavation rod is pulled up from the excavation hole.

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