JP4175635B2 - Slime treatment equipment - Google Patents

Description

  The present invention relates to a slime processing apparatus that discharges and removes slime deposited on the bottom of a drilling hole to the outside of the drilling hole by sucking up with an underwater sand pump.

  In drilling using a stabilizing liquid in the cast-in-place pile method such as the earth drill method, it is inevitable that slime generated during drilling settles and accumulates at the bottom of the hole. However, since the slime deposited on the bottom of the hole causes a reduction in the bearing capacity of the cast-in-place pile or the hole wall itself, the slime on the bottom of the hole is usually used by a slime treatment device mainly composed of an underwater sand pump. Is discharged out of the hole and removed.

  By the way, the slime deposited on the bottom of the hole cannot be easily removed under the simple suction of the stabilizing liquid by the submersible sand pump. Therefore, various slime processing apparatuses are configured in which the slime deposited on the bottom of the hole is suspended in the stabilizing liquid by stirring the stabilizing liquid near the bottom of the hole, and the suspended slime is sucked up together with the stabilizing liquid.

  As an example, the configuration disclosed in Japanese Patent No. 3323988 can be exemplified.

  This slime treatment device uses a screw provided on the drive shaft of the submersible sand pump as a source of the stirring water flow, and the guide plate provided below the stirring water flow in the vertically downward and horizontal radial directions. It is intended to stir the stabilizing liquid in a wider range under the distribution.

  According to the slime processing apparatus having this configuration, it is possible to stir the stabilizing liquid in a relatively wide range. However, the slime that has been crushed and suspended by the stirring water flow in the vertical downward direction diffuses over a wide area under the stirring water flow in the horizontal radial direction, so the slime from the suction port of the submersible sand pump located above it The suction efficiency, that is, the processing efficiency tends to decrease.

  Further, in this configuration in which the guide plate is disposed at the lower position of the submersible sand pump, the screw that is the source of the stirring water flow is separated from the hole bottom by that distance, and accordingly, the flow velocity is reduced. Slime crushing and reduction in floating efficiency are inevitable.

  Here, as another example of this type of slime processing apparatus, there is a configuration disclosed in, for example, Japanese Patent Application Laid-Open No. 2002-88758.

  In the slime treatment apparatus of this another example, the nozzle that enables jetting of air is disposed on the side of the suction port of the submersible sand pump, and according to this, the air against the slime deposited on the bottom of the hole is arranged. Since direct injection becomes possible, the crushing and floating efficiency with respect to the slime at the bottom of the hole is improved as compared with the above known examples. And since the slime which was crushed by the jet and before spreading in a wide range can be sucked in by the suction port of the submersible sand pump located in the vicinity thereof, the processing efficiency is also improved reliably.

  However, in this slime processing apparatus of another example, since the nozzle is provided in the pipe extending in the plane radial direction, an increase in the size of the plane outline is inevitable. Such an increase in the size of the planar outer shape is inferior in adaptability to a small-diameter drilling hole, so there is a possibility that the adaptive diameter of the drilling hole is limited.

  And since the jet range of the steam from a nozzle is narrow, in order to obtain the slime | crush of a wide range at once, many nozzles are needed, Therefore The complexity of the structure cannot be avoided.

Furthermore, in the slime processing apparatus of this other example, a submersible pump for air / water injection is required in addition to a submersible sand pump for sucking up, so that the configuration is increased in size, weight, etc. Also easy to accompany.
Japanese Patent No. 3323988 JP 2002-88758 A

  The problems to be solved are that the conventional configuration improves slime crushing, floating efficiency, and its processing efficiency, but the configuration of the apparatus is complicated, the overall planar outer shape is increased, and It is inevitable to accompany weight increase.

In the present invention according to claim 1 , the extension duct is fixedly connected to the suction port of the submersible sand pump under the sealing at the upper edge and is suspended concentrically from the submersible sand pump. The lower end portion has a duct suction port having a planar shape passing through the center position of the submersible sand pump with an effective suction area equivalent to the suction port of the submersible sand pump.
A propeller-type submerged stirrer that is a separate source from the submerged sand pump and serves as a separately driven stirring water flow generation source is attached to the side surface of the extension duct and provided at a lower position of the submerged sand pump .

Further, in the present invention according to claim 2 , the extension duct is fixedly connected to the suction port of the submersible sand pump under the sealing at the upper edge and is suspended concentrically from the submersible sand pump. In addition, a duct suction port having a substantially single plane shape passing through the center position of the submersible sand pump with an effective suction area equivalent to the suction port of the submersible sand pump is provided at the lower end thereof .
A propeller-type submerged stirrer that is a separate source from the submerged sand pump and serves as a separately driven stirring water flow generation source is attached to the side surface of the extension duct and provided at a lower position of the submerged sand pump.

In the present invention according to claim 3 , the extension duct is fixedly connected to the suction port of the submersible sand pump under the sealing at the upper peripheral edge and hangs concentrically from the submersible sand pump. In addition, a duct suction port having a substantially plane shape passing through the center position of the submersible sand pump has an effective suction area equivalent to that of the submersible sand pump at the lower end thereof .
A propeller-type submerged stirrer that is a separate source from the submerged sand pump and serves as a separately driven stirring water flow generation source is attached to the side surface of the extension duct and provided at a lower position of the submerged sand pump.

In the present invention according to claim 4, the length of the duct inlet at a diameter direction of the water sand pump is longer than the diameter of the water sand pump.

According to the first aspect of the present invention, the propeller-type underwater agitator serving as the stirring water flow generation source is attached to the side surface of the extension duct and arranged at the lower position of the underwater sand pump. since then downwardly depending suction mouth and are disposed, can without arrangement of stirring water source and the suction port to the bottom of the hole near the position involves an increase in the size of the planar outer shape, the adaptability to a small diameter drilling It is reliably improved.

Since the propeller-type underwater agitator is smaller and lighter than a submersible pump for jetting air and the like, it can be easily and sufficiently reduced in size and weight as a slime treatment device .

Furthermore, since the propeller-type underwater stirrer is used as the source of the stirring water flow, the radiation range is surely expanded as compared with the steam water jetted from the nozzle. That is, since the stirring range by the propeller-type underwater stirrer is relatively wide, the number can be sufficiently suppressed as compared with the nozzle or the like, and the configuration can be simplified sufficiently .
Since the duct suction port of the extension duct is formed in a planar shape that passes through the center position of the submersible sand pump, the adaptability to a large-diameter drilling hole or an expanded bottom hole is reliably improved .

According to the second aspect of the present invention, the propeller-type underwater agitator serving as a stirring water flow generation source is attached to the side surface of the extension duct and arranged at the lower position of the underwater sand pump. Because it is placed below the suction port, the source of the stirring water flow and the suction port can be placed near the bottom of the hole without increasing the size of the flat outer shape. Certainly improved.
Since the propeller-type underwater agitator is smaller and lighter than a submersible pump for jetting air and the like, it can be easily and sufficiently reduced in size and weight as a slime treatment device.
Furthermore, since the propeller-type underwater stirrer is used as the source of the stirring water flow, the radiation range is surely expanded as compared with the steam water jetted from the nozzle. That is, since the stirring range by the propeller-type underwater stirrer is relatively wide, the number can be sufficiently suppressed as compared with the nozzle or the like, and the configuration can be simplified sufficiently.
Duct inlet extension duct, which is formed on the flat, substantially letter shape passing through the center position of the underwater sand pump, drilling a larger diameter, or adaptability to拡底hole is surely improved.

According to the third aspect of the present invention, the propeller-type underwater stirrer serving as the stirring water flow generation source is attached to the side surface of the extension duct and arranged at the lower position of the submersible sand pump. Because it is placed below the suction port, the source of the stirring water flow and the suction port can be placed near the bottom of the hole without increasing the size of the flat outer shape. Certainly improved.
Since the propeller-type underwater agitator is smaller and lighter than a submersible pump for jetting air and the like, it can be easily and sufficiently reduced in size and weight as a slime treatment device.
Furthermore, since the propeller-type underwater stirrer is used as the source of the stirring water flow, the radiation range is surely expanded as compared with the steam water jetted from the nozzle. That is, since the stirring range by the propeller-type underwater stirrer is relatively wide, the number can be sufficiently suppressed as compared with the nozzle or the like, and the configuration can be simplified sufficiently.
Duct inlet extension duct, which is formed on the flat, substantially cross-shaped passing through the center position of the underwater sand pump, drilling a larger diameter, or adaptability to拡底hole is surely improved.

Further, according to the present invention according to claim 4 , since the length of the duct suction port in the diameter direction of the submersible sand pump is formed longer than the diameter of the submersible sand pump, the suctionable width can be easily expanded. It becomes possible .

  The slime can be crushed, the reliability of floating can be improved, and the processing efficiency can be improved without complicating the structure, increasing the size of the planar outline, and increasing the weight.

  FIG. 1 is a schematic front view of a slime processing apparatus 10 according to a first embodiment of the present invention. As can be seen from FIG. 1, this slime processing apparatus has a vertical sand water pump 12 as its base. Is formed.

  This submersible sand pump 12 is a so-called vertical shaft type electric submersible sand pump having a fluid suction port 14 at its lower end, and the fluid sucked from the suction port is discharged under the suction. 16 is configured to be discharged from.

  A general commercial product can be used as the submersible sand pump 12, and the basic configuration of the submersible sand pump itself is not the gist of the present invention, and therefore, detailed description of the submersible sand pump is omitted here.

  Here, in the slime treatment apparatus 10 of the present invention, a propeller-type submerged stirrer 18 that is separate from the submerged sand pump 12 is provided at a lower position of the submerged sand pump as a stirring water flow generation source. And at least partially overlapping the submersible sand pump.

  The propeller-type underwater stirrer 18 generates a stirring water flow in the stable liquid in the drilling hole by the rotation of the propeller 18a, and the direction of the stirring water flow is embodied as a downward direction including at least the hole bottom direction.

  In addition, as this propeller type submerged stirrer 18, a general commercially available product can be used, and since the basic configuration of the propeller type submerged stirrer itself is not the gist of the present invention, a detailed description of the propeller type submerged stirrer is omitted.

  Moreover, as a number of this propeller type underwater stirrer 18, two machines can be illustrated, for example. However, the number is not limited to this.

  Further, although the propeller type submerged stirrer 18 is driven separately from the submersible sand pump 12, in terms of its operability, the propeller type submerged stirrer 18 may be a so-called synchronous operation type that is linked to the operation of the submersible sand pump. desirable.

  By the way, in such a configuration in which the propeller-type submerged stirrer 18 is arranged at the lower position of the submerged sand pump 12, a distance corresponding to at least the total length of the propeller-type submerged stirrer between the suction port 14 of the submerged sand pump and the bottom of the hole. Inevitable separation. Therefore, in the present invention, the suspended extension duct 20 having a duct suction port 20a having an effective suction area equivalent to that of the suction port 14 of the submersible sand pump at the lower end thereof is provided at least with respect to the suction port of the submersible sand pump. The duct suction port is defined as a substantial suction port replacing the suction port of the submersible sand pump by being fixedly connected under the sealing at the upper edge.

  As can be seen from FIG. 2 in addition to FIG. 1, in this extended duct 20, a duct suction port 20 a is defined and formed at the lower end of a hollow duct main portion 20 b extending downward, and this duct suction port is It is established as a combination of a plurality of perforations 21.

  The effective suction area of the duct suction port 20a is embodied in the present invention as equivalent to that in the suction port 14 of the submersible sand pump.

  The effective suction area of the suction port here refers to the total area of the perforations that form the suction port, and by making the effective suction area of the duct suction port 20a equivalent to that of the suction port 14 of the submersible sand pump, It becomes possible to secure the suction capacity almost equal.

  In addition, as a planar shape of the duct inlet 20a in this 1st Example, the substantially single character shape as shown in FIG. 2 can be illustrated, for example.

  The extended duct 20 is formed at the upper end of the duct main portion 20b, for example, as a form integrally having a substantially cylindrical mounting base 20c, and the mounting base is fixed around the suction port 14 of the submersible sand pump. The extension duct is connected to and attached to the submersible sand pump.

  Here, the extension duct 20 is embodied as being fixedly connected to the suction port 14 of the submersible sand pump at least under the sealing of the upper edge.

  As shown in FIG. 1, in this first embodiment, the mounting base 20c of the extension duct is placed around the suction port 14 of the submersible sand pump, for example, with the packing material 24 interposed, and this is installed. For example, by fixing by bolting or the like, it is embodied as a connection of the extension duct 20 with the upper peripheral edge sealing to the suction port of the submersible sand pump.

  In such a configuration, since the suction port 14 of the submersible sand pump is covered by the extension duct 20, only the duct suction port 20a of the extension duct is defined as a substantial suction port that replaces the suction port of the submersible sand pump. Will be.

  As can be seen from FIG. 1, in the first embodiment, the perforations formed in the peripheral surface 14a of the suction port 14 of the submersible sand pump are formed by the extension base 20c and the packing material 24. It will be sealed. However, since the perforation (not shown) formed in the lower surface 14b of the suction port 14 of the submersible sand pump is left without being sealed, the functional part of the suction port of the submersible sand pump is maintained without any change. Is done.

  As shown in FIG. 1, in the first embodiment, the propeller type underwater agitator 18 is attached to the extension duct 20 via a support bracket 26 fixed to the duct main portion 20 b of the extension duct. In this embodiment, the vertical downward direction is defined as the flow direction of the stirring water flow by the propeller-type underwater stirrer 18.

  As shown in FIG. 1, the slime processing apparatus 10 having such a configuration is provided with a suspension, for example, by a crane or the like, in the vicinity of the bottom (hole bottom 28) of the hole filled with the injection of the stabilizing liquid and filled. And inserted and subsided. Then, by driving the underwater sand pump 12 and driving the propeller-type underwater agitator 18, a downward (vertically downward) agitated water flow is generated in the stable liquid in the drilling hole as a water flow by the propeller-type underwater agitator.

  As shown in the figure, the propeller submersible agitator 18 is located below the submersible sand pump 12, so that the propeller submersible agitator 18 is placed under the bottom of the hole under insertion and subsidence of the slime treatment device 10 into the drilling hole. It is easy to arrange near 28. Then, by driving the propeller-type underwater stirrer 18 in the vicinity of the hole bottom 28, a strong stirring water flow from the propeller-type underwater stirrer due to the close distance is directly applied to the hole bottom 28.

  By directly applying such a strong stirring water flow to the hole bottom 28, the crushing and floating efficiency with respect to the slime deposited on the hole bottom is reliably increased.

  The slime crushed by this downward, strong stirring water flow rides on the stirring water flow and floats in the stable liquid. Then, by sucking the floated slime from the duct suction port 20a of the extension duct, the slime at the bottom of the hole is discharged and removed from the hole.

  Here, in this invention, since the duct suction port 20a of the extension duct is also arranged near the bottom of the hole due to insertion and subsidence of the slime treatment device 10 into the drilling hole, the stirring water flow from the propeller-type underwater stirrer 18 According to the slime treatment apparatus of the present invention, the slime that has been crushed and floated can be sucked from the duct suction port immediately after the crushing and floating, that is, before being diffused in the stable liquid over a wide area. .

  As described above, according to the slime treatment apparatus 10 of the present invention, it is possible to ensure a strong stirring water flow and to easily and sufficiently suck the slime before being diffused over a wide range. And the improvement of the processing efficiency can be ensured.

  And since the propeller type submerged stirrer 18 used as a stirring water flow generation source is smaller and lighter than a general submersible pump that generates air and the like, the slime treatment apparatus of the present invention using this propeller type submerged stirrer According to No. 10, the overall size and weight can be sufficiently reduced.

  In the present invention, since the propeller-type submerged stirrer 18 is disposed at the lower position of the submerged sand pump 12, the planar shape of the slime treatment device 10 is a side of the submerged sand pump. It will be sufficiently suppressed as compared with the configuration of juxtaposed with each other. That is, according to the present invention, although the propeller-type submerged stirrer 18 is provided in the submersible sand pump 12, an increase in the size of the planar outer shape can be reliably prevented.

  Thus, if the size of the planar outer shape of the slime processing apparatus 10 is suppressed, the adaptability to a small diameter drilling hole is reliably improved.

  Moreover, in the slime processing apparatus 10 of this invention, since the propeller-type underwater stirrer 18 is used as a stirring water flow generation source, the radiation range is surely expanded as compared to the air and the like injected from the nozzle. The That is, since the stirring range by the propeller-type underwater stirrer is relatively wide, the number can be sufficiently suppressed as compared with the nozzle or the like. Therefore, simplification of the configuration can be sufficiently achieved.

  In the first embodiment, two machines are embodied as the number of propeller-type underwater agitators 18, but the number is not limited to this. For example, the number may be embodied as one machine.

  Here, in the first embodiment, the duct suction port 20a of the extension duct is embodied as being formed by the perforation 21 only on the lower end surface of the duct main portion 20b, but it can be positioned near the hole bottom. Therefore, in addition to the lower end surface, a perforation may be provided on the side surface of the lower end portion. However, since the total area of the perforations on the lower end surface and the lower end side surface of the duct main portion 20b is the effective suction area of the duct suction port 20a, in this case, the number of perforations is adjusted below the duct main portion. Necessary between the end face and the lower face.

  Moreover, in the above, although the example of the extension position of the duct suction port 20a of an extension duct is not specifically specified, the extension position of this duct suction port is, for example, as shown in FIG. It is preferably below the propeller 18a of the stirrer.

  In such an extended position of the duct suction port 20a, the duct suction port is easily and surely arranged in the vicinity of the hole bottom, so that the slime processing efficiency is reliably improved.

  Here, the submersible sand pump 12, the propeller-type submerged stirrer 18, and the extension duct 20 are accommodated and disposed in, for example, a substantially cylindrical protective frame 30, and the duct suction port 20a is separated from the hole bottom by the protective frame. It is preferable that the arrangement can be ensured (see the dashed line in FIG. 1).

  With such a configuration, the submersible sand pump 12, the propeller-type submerged stirrer 18 and the extension duct 20 are isolated from external forces, so that the safety of the slime treatment apparatus 10 can be ensured when suspended by a crane or the like. Easy and full. As shown in FIG. 1, by providing a specific gap L1 between the lower end surface of the protective frame 30 and the duct suction port 20a, the duct suction port can be spaced apart from the hole bottom 28 by this gap. Since it can be secured easily, its safety and its work can be facilitated sufficiently.

  The protective frame 30 is a non-closed type having openings on the lower end surface, the peripheral surface, and the like that ensure the flow of the stable liquid inside and outside. In particular, the lower end surface has a smooth stirring water flow. For example, it is preferable to have a rough mesh shape that can ensure fluidity and smooth floating of the slime.

  Further, in the above, the length example of the duct suction port 20a of the extension duct is not particularly specified, but the length L2 of the longitudinal side of the duct suction port is, for example, as shown in FIG. It is preferably longer (larger) than the diameter L3 of the suction port 14 of the pump.

  If it is such a structure, since the effective suction area | region of the duct suction inlet 20a of an extension duct is obtained in a wide range by this long duct suction inlet 20a, the improvement of the suction efficiency can be expected further.

  Furthermore, in this embodiment, the vertically downward direction is defined as the flow direction of the stirring water flow by the propeller-type underwater stirrer 18, but the stirring water flow direction only needs to be downward including at least the hole bottom direction. The propeller type underwater agitator may be set so as to be able to generate a stirring water flow obliquely downward, for example.

  However, if the flow direction of the stirring water flow by the propeller-type underwater stirrer 18 is set to be vertically downward, diffusion of the slime suspended thereby is suppressed within a narrow range, so that it is possible to ensure a higher improvement in processing efficiency.

  Here, in the first embodiment, the planar shape of the duct suction port 20a of the extension duct is embodied as a substantially single character shape, but is not limited to this, for example, a planar substantially cross shape as shown in FIG. In addition, this duct suction port may be formed.

  As can be seen from the slime processing apparatus 110 of FIG. 5 shown as the second embodiment of the present invention, in this second embodiment as well, there is no change in using the submersible sand pump 12 as its substrate. Since it is the same in the second embodiment that the propeller type underwater agitator 18 is disposed at the lower position of the submersible sand pump, the explanation for these uses the same thing as in the first embodiment. It is omitted here.

  In this second embodiment, the duct main portion 120b of the extension duct is formed in a hollow prismatic shape, for example, which does not match the planar shape of the duct suction port 120a, and the duct suction port, And the attachment base 120c of the upper end is connected so that communication is possible.

  Even in such a substantially cross-shaped duct suction port 120a, the effective suction area at the duct suction port is the same as that of the suction port 14 of the submersible sand pump, as in the first embodiment. Formed.

With the duct suction port 120a having a substantially plane shape like this, it is possible to form the length L5 of one side relatively long without leaving a large space between the sides. That is, since a relatively wide range can be defined as the slime suckable range by the duct suction port 120a, the working efficiency can be further improved.

  In addition, the form of the duct suction port 20a in the first embodiment is effective at the time of working with a drilling hole having a small hole diameter, and the form of the duct suction port 120a in the second embodiment is a drilling hole having a large hole diameter, Alternatively, it can be used particularly effectively for an expanded bottom hole whose diameter is expanded.

  Further, as shown in FIG. 5, in the slime processing apparatus 110 of the second embodiment, the submersible sand pump, the propeller-type underwater stirrer, and the extension duct can be accommodated by the protective frame 130. In the form of an example, it is preferable to form the lower end part in the substantially skirt shape as shown in the figure.

  The above-described embodiments are for explaining the present invention, and do not limit the present invention. All modifications, alterations, and the like within the technical scope of the present invention are included in the present invention. It goes without saying that it is done.

It is a schematic front view of a partial fracture of the slime processing apparatus according to the first embodiment of the present invention. It is a schematic perspective view of an extension duct. It is a general | schematic partial side view of the slime processing apparatus mainly having the extension duct. It is a schematic front view of the partial fracture | rupture of the slime processing apparatus which concerns on 2nd Example of this invention. It is a schematic perspective view of the extension duct in 2nd Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Slime processing apparatus 12 Submersible sand pump 14 Submersible sand pump suction port 18 Propeller type underwater agitator 20 Extension duct 30 Protection frame

Claims (4)

In the slime processing device that discharges and removes slime deposited on the hole bottom of the drilling hole outside the drilling hole together with the stabilizing liquid in the drilling hole under the suction of the vertical sand pump as the base.
The extension duct is fixedly connected to the suction port of the submersible sand pump under the upper peripheral seal and hangs concentrically from the submersible sand pump.
This extension duct has a duct suction port having a planar shape passing through the center position of the submersible sand pump with an effective suction area equivalent to the suction port of the submersible sand pump at the lower end thereof ,
A slime characterized in that a propeller-type submerged stirrer, which is a separate and separately driven stirring water flow source, is attached to the side surface of the extension duct and provided at a lower position of the submerged sand pump. Processing equipment. In the slime processing device that discharges and removes slime deposited on the hole bottom of the drilling hole outside the drilling hole together with the stabilizing liquid in the drilling hole under the suction of the vertical sand pump as the base.
The extension duct is fixedly connected to the suction port of the submersible sand pump under the upper peripheral seal and hangs concentrically from the submersible sand pump.
This extension duct has a duct suction port in the shape of a plane that passes through the center position of the submersible sand pump with an effective suction area equivalent to the suction port of the submersible sand pump at its lower end ,
A slime characterized in that a propeller-type submerged stirrer, which is a separate and separately driven stirring water flow source, is attached to the side surface of the extension duct and provided at a lower position of the submerged sand pump. Processing equipment. In the slime processing device that discharges and removes slime deposited on the hole bottom of the drilling hole outside the drilling hole together with the stabilizing liquid in the drilling hole under the suction of the vertical sand pump as the base.
The extension duct is fixedly connected to the suction port of the submersible sand pump under the upper peripheral seal and hangs concentrically from the submersible sand pump.
This extension duct has a duct suction port of a substantially cross-shaped plane passing through the center position of the submersible sand pump with an effective suction area equivalent to the suction port of the submersible sand pump at the lower end thereof ,
A slime characterized in that a propeller-type submerged stirrer, which is a separate and separately driven stirring water flow source, is attached to the side surface of the extension duct and provided at a lower position of the submerged sand pump. Processing equipment. The slime processing apparatus according to any one of claims 1 to 3 , wherein a length of a duct suction port in a diameter direction of the underwater sand pump is longer than a diameter of the underwater sand pump.

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