JP2007247199A - Vertical hole excavation unit, vertical hole excavation subsystem, and vertical hole excavation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vertical hole excavation unit capable of not only discharging objects such as earth, rocks, and fine particles of stones appeared due to excavation onto the ground efficiently and simply but also excavating a hard rock mass. <P>SOLUTION: This vertical hole excavation unit is provided with a rock drilling part 1 for drilling a rock mass by a vibrating rock drilling rod 1a, a cylindrical excavation part 2 driven and rotated around the rock drilling part 1, a main body basic part 3 provided with the excavation part 2 centered on the rock drilling part 1, a crushing part 4 provided between the main body basic part 3 and the excavation part 2, and an earth and rock suction means 5 for sucking and discharging the earth and rocks drilled in the rock drilling part 1, excavated in the excavation part 2, and crushed in the crushing part 4 in the excavation part 2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a vertical hole excavation unit that is used by being attached to the tip of a hydraulic construction machine when excavating a vertical hole mainly for a foundation of a steel tower, a vertical hole excavation subsystem using the vertical hole excavation unit, and these The present invention relates to a vertical hole drilling system that includes a vertical hole drilling unit or a vertical hole drilling subsystem, and that automatically and continuously discharges and stores excavated debris.

  Regarding the excavation of the vertical hole, the techniques of Patent Document 1 and Patent Document 2 by the present applicant have been proposed.

  In Patent Document 1, a telescopic arm that can be expanded and contracted is attached to the tip of a hydraulic excavator placed on the ground in order to perform excavation work at the hole bottom of a vertical hole reliably and strongly, and the telescopic arm is placed at the hole bottom. Techniques have been proposed for excavating while pressing the pressing center of an excavating machine.

  This technology enables more powerful excavation by pressing the excavator from the ground while using a small excavator that can be installed in a limited space at the bottom of the hole. An extra effort is required for discharging the debris generated by the excavation, and it is necessary to rely on a person to operate the excavating machine in an environment of dust generated by excavation.

  Patent Document 2 proposes a vertical hole excavation unit provided with a debris suction means to solve the above problem, and FIG. 10 is an external perspective view showing the vertical hole excavation unit as the background art of the present invention. is there.

  The vertical hole excavation unit 60 shown in FIG. 10 is attached to the tip of a telescopic arm attached to a hydraulic construction machine (not shown) via a ground auger 56 that gives a rotational driving force to the attachment 57. A cylindrical excavation part 51 that rotates together with the earth auger 56, a lid 52 that does not co-rotate with the excavation part 51 and hermetically closes the rear end of the excavation part 51, and A suction port 53 provided in the lid 52 is provided.

  A suction force is applied to the suction port 53 from the ground via the suction pipe 59, and the matter accumulated in the cylindrical excavation part 51 can be sucked and discharged to the ground.

  The excavation part 51 includes a central shaft 51a that is a part connected to the earth auger 56, a cylindrical part 51b that rotates concentrically with the central axis 51a, a tip of the central axis 51a, and a front peripheral end of the cylindrical part 51b. A plurality of rock excavation tips 51c provided respectively.

  With such a configuration, according to the vertical hole excavation unit 60, the debris excavated by the excavation part 51 (including sediment, debris of rock, etc.) is sequentially supplied via the intake port 53 and the intake cylinder 59. Since it is sucked and discharged to the ground, the extra work of discharging debris is saved, and dust generated by excavation is discharged along with this suction and discharge, so the dust environment at the bottom of the hole is improved.

However, this vertical hole excavation unit 60 is excavated by the rotating excavation section 51, and therefore cannot be excavated in the case of a hard rock.
Japanese Patent Laying-Open No. 2003-314185 (FIG. 13) Japanese Patent Laying-Open No. 2005-220609 (FIG. 1)

  The present invention has been made to solve the above-described problems, and can excavate hard rock mass while efficiently and simply discharging materials such as debris and dust generated by excavation to the ground. It is an object of the present invention to provide a vertical hole drilling unit, a vertical hole drilling subsystem, and a vertical hole drilling system.

  The vertical hole excavation unit according to claim 1, comprising: a rock portion that rocks the bedrock with a vibrating rock rod; a cylindrical excavation portion that is driven to rotate around the rock portion; and the rock portion A main body base having the excavation part as a center, a crushing part provided between the main body base and the excavation part, and a rock that has been dredged by the rock formation part and excavated by the excavation part, and crushed by the crushing part. A debris suction means for sucking and discharging debris in the excavation part is provided.

  The vertical hole excavation unit according to claim 2 is dependent on claim 1, and the excavation part is supported by the main body base so as to be rotatable around the peridotite rod, and is rotationally driven from a rotation driving means installed on the main body base. An inner cylindrical portion receiving force, an outer cylindrical portion co-rotating concentrically with the inner cylindrical portion, a plurality of crosspieces connecting the inner cylindrical portion and the outer cylindrical portion, and provided on the front side of the crosspiece A plurality of rock excavation tips, and the plurality of rock excavation tips installed on the plurality of bars are arranged so that the tip ends form a conical spiral as a whole. .

  The vertical hole excavation unit according to claim 3 is dependent on claim 2, and the crushing portion includes a pair of backward crushing tips provided rearward from the back surface of the crosspiece, and a front side from the main body base. A forward crushing tip, and the backward crushing tip and the forward crushing tip have portions overlapping each other in the rotation axis direction of the excavation part, When rotating, the forward crushing tips are configured to pass between the pair of backward crushing tips.

  The vertical hole excavation unit according to claim 4 is dependent on any one of claims 1 to 3, and the debris suction means includes an excavation part that rotates while maintaining airtightness with respect to the main body base, and an inside of the excavation part. And a suction port provided through the main body base.

  The vertical hole excavation unit according to claim 5 is dependent on any one of claims 1 to 4, and includes a unit attachment portion for detachably attaching the vertical hole excavation unit to the hydraulic construction machine on the main body base. It is characterized by.

  The vertical hole excavation unit according to claim 6 is dependent on claim 5, and the unit mounting portion includes a turning means for turning the vertical hole excavation unit with respect to the hydraulic construction machine to be attached. To do.

  The vertical hole excavation subsystem according to claim 7 is provided with a fixing means for fitting to the ground, and a support column that is vertically fixed to the ground by the fitting and fixing means, a lifting unit that moves up and down on the support column, and the lifting and lowering unit. The vertical hole excavation unit according to claim 5 is installed at a tip of the free arm portion, and a hydraulic pressure is provided at an upper end of the support column. A sub-attachment portion for attaching to the construction machine is provided, and the sub-attachment portion is pivotally connected to the support column.

  A vertical hole excavation system according to claim 8 or a vertical hole excavation subsystem according to claim 7, wherein the vertical hole excavation system according to claim 8 is attached to a hydraulic construction machine disposed on the ground. In order to discharge and store the debris sucked by the debris suction means, a debris discharge and storage device arranged on the ground is provided.

  A vertical hole excavation system according to a ninth aspect is dependent on the eighth aspect and includes an exhaust gas purification device for purifying exhaust gas discharged from the debris discharge storage device.

  According to the vertical hole excavation unit according to claim 1, the rock excavation part that rocks the bedrock with the vibrating rock rod, the cylindrical excavation part that is driven to rotate around the rock formation part, A main body base in which the excavation part is installed centering on a rock part, a crushing part provided between the main body base and the excavation part, a rock that has been dredged in the rock part, excavated in the excavation part, and fractured in the crushing part It is equipped with a debris suction means for sucking and discharging debris in the excavated part, so that it is possible to efficiently and easily discharge debris and dust generated by excavation to the ground, while maintaining a hard rock mass. Can excavate.

  According to the vertical hole excavation unit of claim 2, in addition to the effect of claim 1, the excavation part is supported by the main body base so as to be able to rotate around the peridotite rod, and the rotation driving means installed on the main body base An inner cylindrical portion that receives a rotational driving force from the inner cylindrical portion, an outer cylindrical portion that co-rotates concentrically with the inner cylindrical portion, a plurality of crosspieces that connect the inner cylindrical portion and the outer cylindrical portion, and a front side of the crosspiece A plurality of rock excavation tips provided, and the plurality of rock excavation tips installed on the plurality of crosspieces are arranged so that the tip ends form a conical spiral as a whole, The rock excavation tip excavates the surrounding rocks sequentially from the tip to the back, and can excavate efficiently with a smaller driving force.

  According to the vertical hole excavation unit according to claim 3, in addition to the effect of claim 2, the crushing portion includes a pair of backward crushing tips provided from the back surface of the crosspiece toward the rear, and the main body. A forward crushing tip provided forward from the base, and the backward crushing tip and the forward crushing tip have portions overlapping each other in the rotation axis direction of the excavation part, and the backward crushing tip. When the crushing tip rotates, the forward crushing tip is configured to pass between the pair of the backward crushing tips, so that a large piece of rock that has been dredged in the rock portion is more It is crushed into small rock fragments and can be sucked and discharged by debris suction means.

  According to the vertical hole excavation unit of claim 4, in addition to the effect of any one of claims 1 to 3, the debris suction means includes an excavation part that rotates while maintaining airtightness with respect to the main body base, and the excavation part Since the suction port provided through the main body base is provided toward the inside of the main body, the debris in the excavation part can be efficiently sucked and discharged.

  According to the vertical hole excavation unit according to claim 5, in addition to the effect of any one of claims 1 to 4, a unit attachment portion for detachably attaching the vertical hole excavation unit to the hydraulic construction machine is provided on the main body base. Therefore, it is easy to attach to and detach from the hydraulic construction machine.

  According to the vertical hole excavation unit of claim 6, in addition to the effect of claim 5, the unit mounting portion includes a turning means for turning the vertical hole excavation unit with respect to the hydraulic construction machine to be attached. This is convenient because it eliminates the need for excavation due to the protrusion of the vertical hole excavation unit, and it eliminates the need for hydraulic construction equipment.

  According to the vertical hole excavation subsystem according to claim 7, provided with a fitting and fixing means to the ground, a column that is vertically fixed to the ground by the fitting and fixing unit, a lifting unit that moves up and down on the column, A vertical hole excavation unit according to claim 5 is provided at a tip of the free arm portion, and a swivel portion fixed to the elevating portion and a free arm portion fixed to the swivel portion. In addition to the effect of claim 5, the position and direction of the vertical hole excavation unit as a whole are provided with a sub-attachment portion for attaching to the hydraulic construction machine, and the sub-attachment portion is pivotally connected to the support column. The degree of freedom is high, the workability in the vertical hole which is a limited space is good, and the bottom excavation can also be performed.

  According to the vertical hole excavation system of claim 8, in addition to the effect of any of claims 1 to 6 or the effect of claim 7, suction is performed by debris suction means attached to a hydraulic construction machine arranged on the ground. In order to discharge and store the generated debris, it is equipped with a debris discharge storage device placed on the ground, so even if there is a hard rock, the drilling of the vertical hole can be done to some extent by operation from the hydraulic construction machine on the ground Even if it is in a state where it has advanced to the depth of, it is possible to continuously excavate the vertical hole without draining the bottom of the vertical hole, discharge the excavated debris, and store it in a storage bag .

  According to the vertical hole excavation system of the ninth aspect, in addition to the effect of the eighth aspect, since the exhaust purification device for purifying the exhaust discharged from the debris discharge storage device is provided, the surrounding environment is polluted by the exhaust. There is nothing to do.

  Hereinafter, embodiments (examples) of the present invention will be described with reference to the drawings.

  FIG. 1 shows an example of a vertical hole drilling unit according to the present invention. (A) is a conceptual longitudinal sectional view of the main part, and (b) is an embodiment of (a) as viewed from the drilling tip side. 2A is a front view of the vertical hole excavation unit of FIG. 1, and FIG. 2B is a side view thereof.

  This vertical hole excavation unit 10 is used by being attached to a hydraulic construction machine (for example, symbol OK3 in FIG. 9) installed on the ground, and is mainly used for excavation of a vertical hole that serves as a foundation mine for a steel tower or a large building. .

  The vertical hole excavation unit 10 is centered on a rock excavation section 1 that rocks the rock mass with a vibrating rock rod 1 a, a cylindrical excavation section 2 that is driven to rotate around the rock formation section 1, and the rock formation section 1. The main body base 3 with the excavation part 2 installed therein, the crushing part 4 provided between the main body base 3 and the excavation part 2, and the rock excavated by the rock formation part 1 and excavated by the excavation part 2 and crushed by the crushing part 4 And a debris suction means 5 for sucking and discharging debris in the excavation section 2.

  In addition, the vertical hole excavation unit 10 is installed in the main body base 3 and rotational driving means 6 for rotationally driving the excavation part 2 and unit attachment for detachably attaching the vertical hole excavation unit 10 to the hydraulic construction machine OK3. Part 7. The main material of each part from the rock formation part 1 to the unit attachment part 7 is steel unless otherwise specified.

  The peridotite portion 1 includes the above-described peridotite rod 1a and a main body portion 1b that vibrates this peridotite rod 1a in the vertical direction B of FIG. 1A by hydraulic pressure, and is generally commercially available. Things can be adopted.

  The peridotite rod 1a can be attached to and detached from the main body 1b, and an optimum one can be used according to the target of the peridotite.

  In addition, the rock formation part 1 can be attached or detached to the main body base 3, and can also be removed when it is not necessary to rock a hard bedrock. In this case, the weight of the vertical hole excavation unit 10 can be reduced by the weight of the rock portion 1.

  The excavation part 2 is supported by the main body base so as to be rotatable around the peridotite rod 1a, and receives the rotational driving force from the rotational driving means 6, and the outer cylindrical part co-rotating concentrically with the inner cylindrical part 2a 2b, a plurality of crosspieces 2c connecting the inner cylindrical portion 2a and the outer cylindrical portion 2b, and a plurality of rock excavation tips 2d provided on the front side of the crosspiece 2c.

  In addition, the excavation part 2 includes a plurality of peripheral excavation tips 2e provided at the front peripheral end of the outer cylindrical part 2b, and the rear end part of the rotating outer cylindrical part 2b near the main part 3 of the main body base 3. Two upper and lower rotary bearings 2h that rotatably support the outer peripheral rib 2f provided so as to cover the front side, the auxiliary excavation tip 2g provided at appropriate positions of the plurality of crosspieces 2c, and the inner cylindrical portion 2a with respect to the main body base 3. 2i.

  The inner cylindrical portion 2a transmits the rotational driving force from the rotational driving means 6 to the crosspiece 2c and the outer cylindrical portion 2b, and enables rock excavation by the rock excavation tip 2d and the peripheral excavation tip 2e provided thereon. It is formed with a strong wall thickness.

  The inner diameter of the inner cylindrical part 2a is an inner diameter that maintains a gap that does not hinder the rock rock rod 1a from vibrating when the rock rock part 1 is attached to the outer diameter of the rock rock rod 1a. .

  As shown in FIG. 1 (a), the protruding length of the inner cylindrical portion 2a from the main body base 3 spans a plurality of crosspieces 2c from the outer front end of the inner cylindrical portion 2a to the inner periphery of the front end of the outer cylindrical portion 2b. In some cases, the length is longer than the protruding length of the front end circumference of the outer cylindrical portion 2b so as to be a central convex.

The outer cylindrical portion 2b is cylindrical, but when excavated by the vertical hole excavating unit 10, the excavation surface is covered by the front end periphery, and a closed space is formed by the excavation portion 2 and the excavation surface, as will be described later. ,
The earth and stone sucking means 5 also plays a role of allowing the suction force to be suitably exerted.

  In this example, the plurality of rock excavation tips 2d provided on the front side of the plurality of cross beams 2c that are centrally convex are, as shown in the drawing, two cross frames 2 that are positioned to divide the circumference into two equal parts. The top of the rock excavation tip 2d is disposed so as to form a conical spiral as a whole.

  In addition, each rock excavation tip 2d is not provided directly below, but is provided so as to be inclined at a certain angle in the rotation direction T (shown in FIG. 1B) of the excavation unit 2. Therefore, the excavated bedrock is directed to the inner side of the excavation unit 2 as the excavation unit 2 rotates in the rotation direction T.

  The peripheral excavation tip 2e excavates rocks existing in the vicinity of the peripheral part of the excavation part 2 so that the excavation part 2 can enter and enter the rock and excavation part to be excavated as a whole. That is, if there is no such peripheral excavation tip 2e and only the front peripheral end of the cylinder, the above-mentioned airtight effect is obtained, but the front peripheral end is blocked by a hard rock or the like, and the excavation part 2 does not enter. Therefore, this peripheral excavation tip 2e is provided.

  The outer peripheral rib 2f covers the outer front end of the main body base 3 and prevents the suction of air from between the rear peripheral end of the excavating part 2 and the front peripheral end of the main body base 3 as much as possible, and debris sucking means The suction force by 5 reaches the crushed debris in the excavation part 2.

  The auxiliary excavation tip 2g is provided for auxiliary excavation.

  The two rotary bearings 2h and 2i are fixed to the base of the main body and reliably support the inner cylindrical portion 2a by its inner ring. In particular, the upper rotary bearing 2h is constituted by a thrust rotary bearing, and the rock portion 1 It can withstand the upward thrust load that is highly likely to be applied to the inner cylindrical portion 2a during the seismic dredging.

  As described above, the main body base 3 serves as a structural base for installing the rock formation portion 1, the excavation portion 2, and the unit attachment portion 7 on the outside thereof, and is a circular box body. As shown in FIG. 1A, a gear train 6r that constitutes the rotation driving means 6 is accommodated therein.

  A hydraulic motor 6 a serving as a drive source for the rotational drive means 6 is further installed outside the main body base 3, and passes through the main body base 3 at an appropriate position of the main body base 3, inside the excavation section 2. An open suction port 5a is provided.

  The crushing portion 4 includes a set of two backward crushing tips 4a provided from the back surface of the crosspiece 2c toward the rear, and a forward crushing tip 4b provided from the main body base portion 3 toward the front. .

  As shown in FIG. 1 (a), the backward crushing tip 4a and the forward crushing tip 4b have a portion overlapping each other in the rotational axis direction (vertical direction in the figure) of the excavation unit 2, while When the crushing tip 4a rotates, the forward crushing tip 4b is configured to pass between the pair of the backward crushing tips.

  Therefore, a large piece of rock that has been dredged in the dredged rock part 1 also has the effect of gravity and co-rotates in a state where it is stretched over two rotating crushing tips 4a, and the two crushing crushes. It will crash into the forward crushing tip 4b protruding in the middle of the tip 4a, and it will be crushed into smaller rock fragments.

  That is, the crushing part 4 composed of the backward crushing chip 4a and the forward crushing chip 4b has a crushing function of crushing a large piece of rock crushed by the rock formation part 1 into smaller pieces.

  The debris suction means 5 includes an excavation part 2 that rotates while maintaining airtightness with respect to the main body base 3 by the outer peripheral ribs 2f, and a suction unit provided through the main body base 3 toward the inside of the excavation part 2. And an outlet 5a. Suction air V indicated by white arrows in FIG. 1A is supplied to the suction port 5a.

  The outer peripheral rib 2f and the suction port 5a constituting the debris suction means 5 have already been described. However, with respect to the outer peripheral rib 2f, the gap between the excavation part 2 and the main body base 3 interferes with the mutual rotation. There is no need to provide a special air-conditioner as long as the intake of the outside air is limited to such an extent that the suction of the debris from the suction port 5a is not hindered.

  The rotation driving means 6 includes the above-described hydraulic motor 6a and a gear train 6r that transmits the rotational driving force of the hydraulic motor 6a to the inner cylindrical portion 2a at the center of the excavating portion 2, and the gear train 6r includes: A driving gear 6b directly connected to the output shaft of the hydraulic motor 6a, an intermediate large gear 6c meshing with the driving gear 6b, an intermediate small gear 6d concentrically with the intermediate large gear 6c, and an intermediate small gear 6e meshed with the inner cylindrical portion 2a. A fixed driven gear 6e is provided.

  As the drive source of the rotational drive means 6, here, hydraulic pressure is used from the point that hydraulic pressure is used in the rock formation part 1 and there is a hydraulic pressure source nearby, and a large and large driving force can be obtained. If the condition is satisfied, it may be pneumatic or electric.

  Here, a normal spur gear train is used as the gear train 6r of the rotation drive means 6, but the present invention is not limited to this as long as a desired reduction ratio can be obtained in a limited space. For example, a gear train of a worm and a worm wheel gear train, an internal gear attached to the inner side of the outer cylindrical portion 2b, and a pinion gear corresponding thereto may be used.

  The unit mounting portion 7 will be described with reference to FIG. 2. The unit mounting portion 7 is installed on the back surface of the main body base 3 so as to sandwich the rock portion 1 between the rock portion 1, the suction port 5a, and the installation portion of the hydraulic motor 6a. A base portion 7a and a general-purpose mounting portion 7b that is detachably connected to the mounting base portion 7a and includes a detachable coupling hole 7c at the distal end portion of the hydraulic construction machine OK3 are provided.

  In this example, the coupling hole 7c of the general-purpose mounting portion 7b is a pair of left and right that can be fitted and attached to the link hole at the distal end portion of the standardized hydraulic construction machine OK3 with two link pins for coupling. Two sets of coupling holes 7c are formed.

  With such a configuration, according to this vertical hole excavation unit 10, it is attached to the tip of the hydraulic construction machine OK3. As a general rule, the direction of the front end of the vertical hole excavation unit 10 is downward, that is, the vertical hole excavation direction. It can be used to excavate objects including hard rock.

  At this time, even if there is a hard rock that is difficult to be excavated by the rock excavation tip 2d of the excavation part 2, the dredged rock can be formed by the rock rod 1a that vibrates strongly before and after the excavation part 1. It is in a state of being broken into rock pieces in the range restricted to the outer peripheral edge of the excavation part 2 to the maximum extent.

  This large rock fragment is directed to the inside of the excavation section 2 by a rock excavation tip 2d provided so as to scoop up the facing rock fragments with respect to the rotational traveling direction of the excavation section 2, and between the back side portion of the crosspiece 2c and the main body base 3 In the internal space of the excavation part 2, the crushing part 4 is crushed into smaller rock fragments by the interaction of the backward crushing chip 4a and the forward crushing chip 4b.

  The excavation and crushing of the rock is also performed by the rock excavation tip 2d, the peripheral excavation tip 2e, and the auxiliary excavation tip 2g of the excavation part 2. Then, it is sucked and discharged out of the unit 10.

  Thus, according to this vertical hole excavation unit 10, an operator mounted on the hydraulic construction machine OK 3 allows the excavation position of the entire unit 10, the pressure to the excavation target, the seismic movement of the rock formation portion 1, the rotation operation of the excavation portion 2, the debris Even if there is a hard rock, simply by supplying the suction air to the suction means 5, the vertical hole can be continuously excavated without approaching the excavated portion.

  Further, since dust generated during excavation is sucked and discharged by the debris suction means 5, the problem of environmental deterioration near the excavation site due to dust is solved.

  That is, according to the vertical hole excavation unit 10 of the present invention, it is possible to excavate hard rock mass while efficiently and simply discharging the generated materials such as debris and dust generated by excavation to the ground.

  In addition, the effect of the vertical hole excavation unit 10 of the present invention that enables two functions, such as excavation work including such hard rock and suction and discharge of debris generated by excavation, with one hydraulic construction machine OK3, When the excavation site is wide, and many hydraulic construction machines can be arranged on a general flat land, and the excavated debris can be discharged and removed with a hydraulic excavator, etc. Will not feel much.

  However, when drilling a vertical hole as a foundation hole for a high-voltage power transmission tower in a mountainous area, it is difficult to secure a large flat area as an excavation site. The effect of the vertical hole excavation unit 10 that enables excavation and discharge of debris is great.

  In addition, the vertical hole excavation unit 10 of the present invention further includes a rock formation portion 1 and a crushing portion 4, and even if it is a hard rock, it can be rocked, crushed, and excavated debris can be sucked and discharged. The effect is even greater.

  Furthermore, according to this vertical hole excavation unit 10, as will be described later, the depth of the vertical hole is increased, and in other cases, manual work at the bottom of the hole or change of the tip excavator is necessary. In addition, even if it is impossible to discharge the debris with a hydraulic excavator, it is possible to operate from the ground or from the upper part of the vertical hole, and it is called excavation work including hard rock mass and suction discharge of debris generated by excavation The industrial significance of the effect of the present invention in which two functions can be performed by one hydraulic construction machine is further increased.

  FIG. 3 shows another example of the vertical hole excavation unit of the present invention, in which (a) is a front view thereof and (b) is a side view thereof. Accordingly, the same parts as those already described are denoted by the same reference numerals and redundant description is omitted. In addition, when there is a separate code for each set of parts, to avoid complications, only the code for the set should be shown, and for each part, only the parts necessary for the description are required. May be indicated.

  Compared with the vertical hole excavation unit 10 of FIGS. 1 and 2, this vertical hole excavation unit 10A has a vertical hole excavation unit with respect to the general-purpose mounting portion 7b between the mounting base 7a and the general-purpose mounting portion 7b of the unit mounting portion 7A. The point which is further provided with the turning means 8 which turns the attachment base 7a side of 10A is different.

  The turning means 8 incorporates a hydraulic motor or an electric motor, can rotate only the rotating portion 8b relative to the fixed portion 8a, and can be fixed so that both of them do not rotate at a position of a desired rotation angle. Is.

  In other words, the turning means 8 functions as a turning means that can change the orientation of the vertical hole excavation unit 10A relative to the hydraulic construction machine even if the hydraulic construction equipment to which the unit 10A is attached does not rotate.

  According to the swivel means 8 as described above, when the hydraulic pump 6a protrudes from the main body base 3 due to the location of the main body base 3 as in the vertical hole excavation unit 10A of the present invention, When excavating along the digging, the digging remains as much as this bulge, but the swiveling means 8 can be swung only on the mounting base 7a side of the vertical hole excavating unit 10A so that the bulging does not get in the way. .

  On the other hand, when there is no such turning means 8, the hydraulic construction machine on the ground is moved and rotated around the excavated vertical hole, and as a result, the protrusion of the vertical hole excavating unit 10 </ b> A is left in the portion left behind. It is necessary to excavate so as not to come, and a large-scale operation is necessary, and this operation is not easy when the vertical hole excavation unit 10A is in a deep hole.

  In addition, when the size of the excavation site is limited as described above, it may not be possible to handle such a hydraulic construction machine itself. The swiveling means 8 can solve such a problem, although a great extra effort such as changing the direction of the construction machine is required.

  FIG. 4 shows another example of the vertical hole excavation unit of the present invention, where (a) is a front view thereof and (b) is a side view thereof.

  This vertical hole excavation unit 10B is common to the vertical hole excavation unit 10A of FIG. 3 in that the turning means 8 is interposed in the unit mounting portion 7B, but a general-purpose mounting portion 7d attached to the hydraulic construction machine is coupled. The difference is that it has a hole 7e.

  The coupling hole 7e is attached to the tip of a telescopic arm that is replaceably attached to the tip of a hydraulic construction machine, and is a pair of left and right pairs that can be fitted and attached with a single link pin. It is a hole 7e.

  The vertical hole excavation unit 10B provided with such a general-purpose mounting portion 7d is used to excavate a deep portion of the vertical hole, which requires less excavation direction of the vertical hole excavation unit 10B than directly below, Even in this case, the turning means 8 is beneficial because it avoids the protrusion of the unit 10B from the excavating section 2 and does not leave any moat, and it is not necessary to run a hydraulic construction machine on the ground.

  The three types of vertical hole excavation units 10, 10 </ b> A, and 10 </ b> B described above share the same portion below the attachment base portion 7 a, whether or not the swivel means 8 are interposed, and whether the general-purpose attachment portions 7 b and 7 d are angle-variable attachments, Since there is only a difference as to whether or not this is the case, it is possible to change from any type to any other type by detaching and replacing these swiveling means 8 and general-purpose mounting portions 7b and 7d.

  5 is an overall configuration diagram conceptually showing an example of the vertical hole drilling system of the present invention using the vertical hole drilling unit of FIG. 4, and FIG. 6 shows an exhaust purification device used in the vertical hole drilling system of FIG. It is shown conceptually, (a) is a longitudinal sectional view thereof, and (b) is a CC sectional view of (a).

  This vertical hole excavation system 30 discharges and stores the debris sucked by the debris suction means 5 with the vertical hole excavation unit 10B attached to the tip of the telescopic arm TA of the hydraulic construction machine OK1 equipped with the telescopic arm TA. Therefore, the debris discharge storage device 21 arranged on the ground is provided, and the excavation of the vertical hole VH has progressed to a certain depth.

  The debris discharge storage device 21 separates and collects the debris and dust sucked and discharged from the air for sucking and discharging, and a conveyor 21b that conveys the debris collected by the collector 21a. And a storage bag 21c for storing debris conveyed by the conveyor 21b, a suction device 21d for supplying suction air for sucking and discharging debris through the collector 21a, and an exhaust discharged from the suction device 21d. An exhaust purification device 22 for purification and an intake / exhaust duct 21e are provided.

  The intake / exhaust duct 21e connects the suction port 5a of the vertical hole excavation unit 10B and the collector 21a, and the collector 21a and the suction device 21d so that the suction air of the suction device 21d reaches the vertical hole excavation unit 10B. I have to.

  The intake / exhaust duct 21e connects the suction device 21d and the exhaust purification device 22 so that the exhaust gas from the suction device 21d is purified by the exhaust purification device 22.

  According to the vertical hole excavation system 30 having such a configuration, the vertical hole excavation unit 10B is used and the debris discharge storage device 21 is provided. Therefore, even when there is a hard rock, it can be operated by the hydraulic construction machine OK1 on the ground. Even if the excavation of the vertical hole VH has progressed to a certain depth, the operator does not enter the bottom of the vertical hole VH, continuously excavating the vertical hole VH, and discharging the excavated debris And can be stored in the storage bag 21c.

  Further, in the excavation in this case, there is no need to waste time because it is not necessary to change the vertical hole excavation unit 10B to a rock drill according to the hardness of the rock in the excavation part or to discharge the excavated debris separately. Is efficient.

  Further, in the case of this vertical hole excavation unit 10B, the swiveling means 8 is provided so that the problem of the remaining moat due to the protrusion of the vertical hole excavation unit 10B can be solved, so that the hydraulic construction machine OK1 on the ground is connected to the vertical hole VH. The forward and backward movement and the telescopic arm TA need only be swung around the hydraulic construction machine OK1, which is advantageous for excavation at a narrow excavation site.

  Furthermore, according to this vertical hole excavation system 30, since the exhaust purification device 22 is provided, the surrounding environment is not polluted by the exhaust.

  In addition, since the exhaust of the suction device 21d only includes earth and sand dust from excavation, the surrounding environment is, for example, in the mountains and temporary contamination with earth and sand dust that is a natural object does not cause an environmental problem. In that case, the exhaust purification device 22 is not necessarily required because the exhaust may be exhausted as it is.

  Moreover, this example is a case where the excavation site is a site for excavating a vertical shaft for transmission line towers, roads and the like are not maintained in the mountains, and the debris discharged by the cable transport device is transported Therefore, the collected debris is stored in the storage bag 21c so as to be adapted thereto, but when a large transport vehicle can be used, the large transport vehicle directly from the tip of the conveyor 21b or the collector 21a. Can be stored and transported.

  Therefore, in such a case, the storage bag 21c and the conveyor 21b are not necessary.

  Next, the exhaust purification device 22 will be described with reference to FIG.

  This exhaust purification device 22 has an exhaust AI from the suction device 21d in a circular tangential direction above a cylindrical main body 22a whose both ends are closed and a main body 22a used with a cylindrical shaft centered. The exhaust inlet 22b is provided so that water is introduced, and the shower portion 22c that sprays or radiates water into the exhaust flow AC that has been introduced and turned into a swirling flow is provided.

  The exhaust purification device 22 also includes a pump 22d for supplying water to the shower unit 22c, a water tank 22e for storing water W supplied to the pump 22d, a swirling flow in a wet state, receiving water radiation. A trapezoidal cone-shaped filter 22f that removes dust from the earth and sand and passes clean air from the exhaust flow AC is provided.

  The exhaust purification device 22 additionally includes a cylindrical portion 22g that receives the filter 22f at the lower portion, an exhaust cylinder 22h for discharging clean air AO in the internal space formed by the filter 22f and the cylindrical portion 22g, and a cylindrical portion. An overflow hole 22i is provided for returning the supernatant water of the mixture of the water stored in the portion between 22g and the main body 22a and the separated dirt dust to the water tank 22e.

  The filter 22f has a mesh shape using water-absorbing or hydrophilic fiber yarns, and the mesh fineness (mesh) is from the level of a mosquito repellent to the level of a monkey for cooking at home. However, it is not limited to this, and is determined by experiment.

  Soil dust is gradually accumulated in a portion between the cylindrical portion 22g and the main body portion 22a, and this earth and sand is appropriately removed from an opening (not shown) provided in the main body portion 22a. .

  According to the exhaust gas purification device 22 having such a configuration, water is radiated to the swirling exhaust gas AC, so that moisture is efficiently given to the swirling exhaust gas AC, and thus the exhaust gas becomes a swirling flow in a moist state. Since the dirt and dust are separated from the flow AC by the hydrophilic filter 22f, the earth and sand can be efficiently separated as a whole.

  In the experiments of the present inventor, it has been found that at least 70% of the earth and sand dust contained in the exhaust from the suction device 21d can be removed.

  Further, according to the exhaust gas purification device 22, since the water radiated to the swirling exhaust gas AC is reused, it is suitable for use in a mountainous area where no water is supplied.

  FIG. 7 is a view showing an example of a hydraulic construction machine provided with the vertical hole excavation subunit of the present invention using the vertical hole excavation unit of FIG. 1, and FIG. 8 is an example of a usage mode of the hydraulic construction machine of FIG. FIG.

  The hydraulic construction machine OK2 shown in FIG. 7 is a so-called hydraulic excavator, with the excavator portion at the tip removed, and a vertical hole excavation subunit 20 using the vertical hole excavation unit of FIG. 1 instead of the excavator portion. Is attached in a removable manner.

  The hydraulic construction machine OK2 can move, turn and lift the vertical hole excavating subunit 20 with the vertical hole excavating subunit 20 installed, and the vertical hole excavating subunit 20 can be used at any place.

  The vertical hole excavation subunit 20 is provided with a fitting and fixing means 12 to the ground, and is fixed to the support 11 that is vertically fixed to the ground, an elevating part 13 that moves up and down on the support 11, and the elevating part 13. A turning part 14 and a free arm part 15 fixed to the turning part 14 are provided.

  The vertical hole excavation unit 10 shown in FIG. 1 is installed at the tip of the free arm portion 15.

  A sub-mounting portion 16 for mounting on a hydraulic construction machine is provided at the upper end of the column 11, and this sub-mounting portion 16 supports the mounting portion 16a to the upper end of the column 11 and the mounting portion 16a so as to be rotatable about a vertical axis. The rotary part 16b is connected to the rotary part 16b, and is provided with a universal attachment part 16c that is attachable to the tip of the hydraulic construction machine OK2 and attachable to the front end of the hydraulic construction machine OK2.

  That is, the column 11 can be attached to and detached from the tip of the hydraulic construction machine OK2 via the sub-mounting portion 16, and can be freely angled around the horizontal axis, and the entire column 11 can be rotated about its longitudinal axis. It is attached.

  According to the vertical hole excavation subunit 20 having such a configuration, the vertical hole can be excavated at an arbitrary place by attaching it to the hydraulic construction machine OK2, and the subunit 20 is vertically supported by the column 11 that can rotate itself. The vertical hole excavation unit 10 can be moved up and down by the elevating unit 13, and the swivel unit 14 can swing around the column 11 of the vertical hole excavating unit 10.

  Further, according to the vertical hole drilling subunit 20, the vertical direction of the vertical hole drilling unit 10 can be freely set by the free arm portion 15, and the position and direction of the vertical hole drilling unit 10 can be freely set as a whole. High degree of workability in a vertical hole that is a limited space.

  In addition, according to this vertical hole excavation subunit 20, since the vertical hole excavation unit 10 is provided at the tip, the effect of the subunit 20 as a whole is also exhibited.

  When this vertical hole drilling subunit 20 is used, even if it is in the vertical hole, the position and orientation of the entire vertical hole drilling subunit 20 can be freely changed. There is little need to be able to swivel with respect to the free arm portion 15, and here, the vertical hole excavation unit 10 does not have the swiveling means 8.

  However, even in this case, the vertical hole excavation unit 10A provided with the turning means 8 may be used.

  The case where this vertical hole drilling subunit 20 is used in the vertical hole VH will be described with reference to FIG. This figure shows a state where excavation of the vertical hole VH has progressed and the vertical hole excavation subunit 20 supported by the hydraulic construction machine OK2 is almost fitted into the vertical hole VH. ing.

  In such a state, since it is difficult to operate the vertical hole excavation subunit 20 while sitting on the cab of the hydraulic construction machine OK2, an operation cage 18 as shown in FIG. 8 may be used.

  The operation car 18 is a car body that accommodates a worker and can be operated by the worker, and can be locked at an arbitrary position on the peripheral wall of the vertical hole VH. 20 is provided with a hydraulic pressure supply means 18a serving as a hydraulic pressure source for the whole 20, a work chair 18b, and an operation lever 18c.

  By this operation lever 18c, the vertical position setting of the elevating part 13 is maintained, the rotation angle setting of the turning part 14 is maintained in the horizontal plane, the vertical direction of the vertical hole excavation unit 10 by the free arm part 15, the vertical hole excavation unit 10 itself Since the operation can be performed while looking at the vertical hole excavation unit 10, the operability is good.

  At this time, since the position of the operation cage 18 is originally away from the excavation portion by the vertical hole excavation unit 10, the influence of dust due to excavation is small, but the generated dust is also sucked and discharged by the vertical hole excavation unit 10. The effect is less.

  This operation car 18 may be used not only in such a vertical hole but also in combination with the vertical hole excavation subunit 20 on the ground, or a vertical hole combined with the hydraulic construction machine OK1 of FIG. In the case of the excavation unit 10B, it may also be used in the case of the vertical hole excavation unit 10A combined with the hydraulic construction machine OK3 of FIG.

  Further, in the excavation of the vertical hole VH by the vertical hole excavation subunit 20, the vertical hole excavation unit 10 can be oriented not only directly below but also obliquely. The excavation of the part WH is also possible.

  The vertical hole VH provided with such an expanded bottom portion WH is effective for making it difficult to remove from the ground when a force in the direction of pulling out the base of the steel tower acts.

  Moreover, this vertical hole excavation subunit 20 may be attached to the tip of the telescopic arm TA of the hydraulic construction machine OK1 to which the telescopic arm TA shown in the fourth embodiment of FIG. 5 is mounted, as shown in the sixth embodiment of FIG. The slide arm SA may be attached to the tip of the slide arm SA of the hydraulic construction machine OK3. In this case, a synergistic effect of the effects of the hydraulic construction machines OK1 and OK3 and the unit 20 is exhibited.

  FIG. 9 is a diagram illustrating an example of a hydraulic construction machine including the vertical hole excavation unit of FIG. 3.

  This hydraulic construction machine OK3 is provided with a slide arm SA that can be expanded and contracted to a certain extent at the tip, and can be operated to change the angle of the one attached to the tip. The vertical hole excavation unit 10A in FIG. Attached to the tip of the SA, the vertical angle can be set.

  According to the vertical hole excavation unit 10A attached to the hydraulic construction machine OK3 with the slide arm SA, in addition to the basic effects of the vertical hole excavation unit 10A, the excavation position can be freely determined, The effect is that the direction can also be set.

  Further, in this case, since the vertical hole excavating unit 10A is provided with the swivel means 8, this can solve the problem of leaving the moat due to the protrusion of the vertical hole excavating unit 10A, so that the hydraulic construction machine OK3 on the ground can have the vertical hole VH. On the other hand, the forward and backward movement and the slide arm SA need only be swung around the hydraulic construction machine OK3, which is advantageous for excavation at a narrow excavation site.

  From the description of the above embodiments, it is understood that the present invention includes the following configurations and operational effects.

  (1) The vertical hole excavation unit 10 includes a rock excavation part 1 for dredging the rock with a vibrating rock rod 1a, a cylindrical excavation part 2 that is driven to rotate around the rock formation part 1, and a rock formation part. A main body base 3 having an excavation part 2 centered on 1, a crushing part 4 provided between the main body base 3 and the excavation part 2, and a crushing part that has been drilled by the excavation part 1 and excavated by the excavation part 2. Since there is a debris suction means 5 that sucks and discharges the debris in the excavation part 2 crushed in (1), the debris and dust generated by excavation are efficiently and easily discharged to the ground. You can also excavate hard rock.

  (2) The excavation part 2 of the vertical hole excavation unit 10 is supported by the main body base 3 so as to be rotatable around the peridotite rod 1a, and receives the rotational driving force from the rotational driving means 5 installed on the main body base 3. A portion 2a, an outer cylindrical portion 2b co-rotating concentrically with the inner cylindrical portion 2a, a plurality of crosspieces 2c connecting the inner cylindrical portion 2a and the outer cylindrical portion 2b, and a plurality of bars provided on the front side of the crosspiece 2c The rock excavation tip 2d is provided, and the plurality of rock excavation tips 2d installed on the plurality of crosspieces 2c are arranged so that the tip ends form a conical spiral as a whole (FIG. 1). The rock excavation tip 2d excavates the rock in order from the tip to the rear, and can efficiently excavate with a smaller driving force.

  (3) The crushing portion 4 of the vertical hole excavation unit 10 is a pair of two pieces of backward crushing tips 4a provided from the back surface of the crosspiece 2c toward the rear, and the front provided from the main body base 3 toward the front. When the backward crushing tip 4a rotates, the backward crushing tip 4a and the forward crushing tip 4b have portions overlapping each other in the rotation axis direction of the excavation unit 2. Since the forward crushing tip 4b is configured to pass between the pair of backward crushing tips 4a (FIG. 1), the large rock fragmented by the rock portion 1 becomes a smaller fragment. It is crushed and can be sucked and discharged by the debris suction means 5.

  (4) The debris suction means of the vertical hole excavation unit 10 is provided so as to penetrate the main body base 3 toward the inside of the excavation part 2 and the excavation part 2 rotating while maintaining airtightness with respect to the main body base 3 Since the suction port 5a is provided (FIG. 1), the debris in the excavation part 2 can be sucked and discharged efficiently.

  (5) Since the vertical hole excavation unit 10 includes the unit attachment portion 7 (FIG. 2) for detachably attaching the vertical hole excavation unit 10 to the hydraulic construction machine on the main body base 3, It is detachable and easy.

  (6) The vertical hole excavation units 10A and 10B are provided with turning means 8 for turning the vertical hole excavation unit with respect to the hydraulic construction machine to be attached to the unit attachment portions 7A and 7B (FIGS. 3 and 4). Therefore, the excavation of the vertical hole excavation units 10A and 10B is eliminated, so that it is not necessary to operate the hydraulic construction machine, which is convenient.

(7) The vertical hole excavation subsystem 20 includes an anchoring means 12 for fixing to the ground, a support column 11 that is vertically fixed to the ground, an elevating unit 13 that moves up and down on the support column 11, and an elevating unit 13 A fixed revolving unit 14 and a free arm unit 15 fixed to the revolving unit 14, and the vertical hole excavation unit 10 of the free arm unit 15 is installed;
At the upper end of the support 11, a sub-attachment part 16 for attaching to the hydraulic construction machine OK 2 is provided, and the sub-attachment part 16 is pivotally connected to the support 11 (FIGS. 7 and 8). By attaching to the OK 2, the vertical hole can be excavated at an arbitrary location, and the subunit 20 can be rotated in the vertical hole by the support column 11 that can rotate itself. The swivel unit 14 can swing around the support column 11 of the vertical hole excavation unit 10.

  Further, according to the vertical hole drilling subunit 20, the vertical direction of the vertical hole drilling unit 10 can be freely set by the free arm portion 15, and the position and direction of the vertical hole drilling unit 10 can be freely set as a whole. High degree of work, good workability in a vertical hole, which is a limited space, and widening excavation is possible.

  (8) The vertical hole excavation system 30 is provided by one of the vertical hole excavation units 10, 10 </ b> A, and 10 </ b> B, or the vertical hole excavation subsystem 20 and the debris suction unit 5, which are attached to a hydraulic construction machine disposed on the ground. In order to discharge and store the sucked debris, it is equipped with a debris discharge and storage device 21 arranged on the ground (FIG. 5), so even if there is a hard rock, it can be operated from the ground hydraulic construction machine OK1. Even if the excavation of the vertical hole VH has progressed to a certain depth, the operator does not enter the bottom of the vertical hole VH, continuously excavating the vertical hole VH, and discharging the excavated debris And can be stored in the storage bag 21c.

  (9) Since the vertical hole excavation system 30 includes the exhaust gas purification device 22 for purifying the exhaust gas discharged from the debris discharge storage device 21, the surrounding environment is not polluted by the exhaust gas.

  (10) The vertical hole excavation unit 10 includes the peripheral excavation tip 2e in the excavation part 2, and excavates the rock existing near the peripheral edge of the excavation part 2 by the peripheral excavation chip 2e, so that the excavation part 2 is excavated as a whole. Demonstrates the effect of being able to enter the target rock and excavation area.

  (11) The vertical hole excavation subunit 20 may be attached to the tip of the telescopic arm TA of the hydraulic construction machine OK1 to which the telescopic arm TA shown in the fourth embodiment of FIG. 5 is mounted, as shown in the sixth embodiment of FIG. The slide arm SA may be attached to the tip of the slide arm SA of the hydraulic construction machine OK3. In this case, a synergistic effect between the effects of the hydraulic construction machines OK1 and OK3 and the effect of the unit 20 is exhibited.

  In the above description, the embodiments of the present invention, the configuration based on their comprehensive concept, and the operational effects have been described. However, the vertical hole drilling unit, the vertical hole drilling subsystem, and the vertical hole drilling system of the present invention are not limited to these. It is not limited.

  Moreover, about the various modifications demonstrated in the said Example, it is not limited to the illustrated combination, All the possible combinations which are not illustrated are also included.

  The vertical hole drilling unit, vertical hole drilling subsystem and vertical hole drilling system according to the present invention can efficiently and easily discharge a generated material such as debris and dust generated by excavation to the ground, It can be suitably used for excavating a vertical hole that is required to be excavated.

An example of the vertical hole excavation unit of this invention is shown, (a) is the conceptual principal part longitudinal cross-sectional view, (b) is the external view which looked at what embodied (a) from the excavation front end side. (A) is a front view of the vertical hole excavation unit of FIG. 1, and (b) is a side view thereof. The other example of the vertical hole excavation unit of this invention is shown, (a) is the front view, (b) is the side view. The other example of the vertical hole excavation unit of this invention is shown, (a) is the front view, (b) is the side view. The whole block diagram which shows notionally an example of the vertical hole drilling system of this invention using the vertical hole drilling unit of FIG. FIG. 6 conceptually shows an exhaust purification device used in the vertical hole excavation system of FIG. 5, (a) is a longitudinal sectional view thereof, and (b) is a CC sectional view of (a). The figure which shows an example of the hydraulic construction machine provided with the vertical hole drilling subunit of this invention using the vertical hole drilling unit of FIG. The figure which shows an example of the usage condition of the hydraulic construction machine of FIG. The figure which shows an example of the hydraulic construction machine provided with the vertical hole excavation unit of FIG. External perspective view showing a vertical hole excavation unit as a background art of the present invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Coral part 1a Coral rod 2 Excavation part 2a Inner cylindrical part 2b Outer cylindrical part 2c Pier 2d Rock excavation tip 3 Main body base 4 Crushing part 4a Backward crushing chip 4b Forward crushing chip 5 Debris suction means 5a Inlet 6 Means 7 to 7B Unit mounting portion 8 Turning means 10 to 10B Vertical hole excavating unit 11 Post 12 Insertion fixing means 13 Lifting portion 14 Turning portion 15 Free arm portion 16 Sub mounting portion 18 Operation cage 20 Vertical hole excavating subsystem 21 Debris discharge storage Equipment 22 Exhaust gas purification equipment 30 Vertical hole drilling system OK1-OK3 Hydraulic construction equipment

Claims (9)

  A rock portion that rocks the bedrock with an oscillating rock rod, a cylindrical excavation portion that is driven to rotate around the rock portion, and a main body base on which the excavation portion is installed around the rock portion A crushing part provided between the main body base and the excavation part, and a debris suction that sucks and discharges the debris in the excavation part that has been excavated by the excavation part and crushed by the excavation part. And a vertical hole excavation unit. The excavation part is supported by the main body base so as to be rotatable around the peridotite rod. An outer cylindrical portion, a plurality of crosspieces connecting the inner cylindrical portion and the outer cylindrical portion, and a plurality of rock excavation tips provided on the front side of the crosspiece,
The vertical hole excavation unit according to claim 1, wherein the plurality of rock excavation tips installed on the plurality of bars are arranged so that the tip ends form a conical spiral as a whole.   The crushing section includes a pair of backward crushing tips provided backward from the back surface of the crosspiece and a forward crushing tip provided forward from the main body base, and the backward crushing While the tip and the forward crushing tip have portions overlapping each other in the rotation axis direction of the excavation part, when the backward crushing tip rotates, the forward crushing tip is a pair of the two. The vertical hole excavation unit according to claim 2, wherein the vertical hole excavation unit is configured to pass between the backward crushing tips.   The debris suction means includes a drilling portion that rotates while maintaining airtightness with respect to the main body base, and a suction port provided through the main body base toward the inside of the drilling portion. The vertical hole excavation unit according to any one of claims 1 to 3.   The vertical hole excavation unit according to any one of claims 1 to 4, further comprising a unit attachment portion for detachably attaching the vertical hole excavation unit to the hydraulic construction machine at the main body base.   The vertical hole excavation unit according to claim 5, wherein the unit attachment portion includes a turning means for turning the vertical hole excavation unit with respect to the hydraulic construction machine to be attached. A supporting column that is fitted and fixed to the ground, and is vertically fixed to the ground by the inserting and fixing unit, a lifting unit that moves up and down on the column, a swivel unit that is fixed to the lifting unit, and the swivel unit The vertical hole excavation unit according to claim 5 is installed at the tip of the free arm portion.
A vertical hole excavation subsystem comprising a sub attachment portion for attaching to a hydraulic construction machine at an upper end of the support column, the sub attachment portion being pivotally connected to the support column.   The vertical hole excavation unit according to any one of claims 1 to 6 or the vertical hole excavation subsystem according to claim 7, which is attached to a hydraulic construction machine disposed on the ground, and debris sucked by debris suction means is discharged. And a debris discharge and storage device arranged on the ground for storage.   The vertical hole excavation system according to claim 8, further comprising an exhaust gas purification device for purifying exhaust gas discharged from the debris discharge storage device.

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