JP7294725B1 - Method and equipment for removing soil stuck to inner wall of suction hose by suction excavation method - Google Patents

Abstract

A method for easily removing waste soil clinging to the inner wall of a suction hose when performing a suction excavation method using a suction excavation system is provided. [Solution] A suction excavation construction method using a suction earth discharge vehicle equipped with a vacuum for sucking discharged earth and a tank for storing the suctioned earth, and a suction hose connected to the suction earth discharge vehicle from a mining hole. A method for removing waste soil clinging to the inner wall of a suction hose, comprising the step of attaching a cylindrical device large enough to contact the inner wall of the hose to the tip of the suction hose (S02), and attaching it to the rear of the device. A step of holding the rope (S03), and then a step of sucking or pumping from the vacuum toward the tank so that the instrument moves along the inner wall of the hose from the tip to the tank (S04). and a step (S05) in which the operator grasps how far the instrument has been sucked by the sucked length. [Selection drawing] Fig. 2

Description

TECHNICAL FIELD The present invention relates to a method for removing soil clinging to the inner wall of a suction hose used in a method of suction excavating soil or the like, and a tool used in the method.

When carrying out underground plumbing work for electricity, telecommunications, gas, water and sewerage, etc., or installing objects such as utility poles, signals, signs, roadside trees, streetlights, etc., the soil at the location where the pipes or objects are installed must be excavated. be. As one of the construction methods for excavating the soil in this way, a suction excavation construction method for excavating while sucking the earth and sand is known. As a suction excavation system used in such a suction excavation method, for example, Patent Document 1 below discloses an attachment for excavating soil, a suction device for sucking excavated earth and sand, and a suction device for connecting the attachment and the suction device. A configuration is disclosed having a hose.

JP 2017-53206 A

In the suction excavation system configured as described above, the excavated earth and sand is transferred from the excavated hole to the tank via the suction hose, but at that time, the discharged earth (excavated earth and sand) adheres to the inner wall of the suction hose. When the discharged soil adheres to the inner wall of the suction hose and accumulates in this way, the efficiency of discharging soil is lowered, and the suction hose may be clogged. Therefore, when using the suction excavation system, it is necessary to remove the waste soil clinging to the inner wall of the suction hose. However, it is particularly troublesome to remove the waste soil adhering to the inner wall of the suction hose at a portion away from both ends. Moreover, when performing such an earth removal operation during suction excavation, the suction hose must be detached from the suction device each time and reattached after the earth removal, which is troublesome.

In view of the circumstances as described above, the present invention provides a simple method capable of removing waste soil clinging to the inner wall of the suction hose when performing the suction excavation method using the suction excavation system described above, and , to provide an instrument suitable for the method.

In the present invention, a suction excavation construction method using a suction earth discharge vehicle equipped with a vacuum for sucking the discharged earth and a tank for storing the suctioned earth, and a suction hose connected to the suction earth discharge vehicle from a mining hole. A method for removing soil clinging to the inner wall of a suction hose, comprising a step of attaching a cylindrical device large enough to contact the inner wall of the hose to the tip of the suction hose, and a rope attached to the back of the device. Then, by sucking or pumping from the vacuum toward the tank, the instrument moves along the inner wall of the hose from the tip to the tank, and at the same time, the instrument and the rope attached to the instrument are sucked. From the step of grasping the position of the device in the suction hose from the length of the part of the rope sucked into the suction hose when moving along the inner wall of the hose from the tip of the suction hose toward the tank Become.

Further, the above method may include a step of pumping the device from the vacuum of the suction earth-discharging vehicle in a direction opposite to the direction of the tank after removing the soil by suction.

Further, in the present invention, the cylindrical instrument used for the above-mentioned suction excavation method has an uneven shape in the direction of the tank so as not to damage the inner wall, and in the opposite direction, the suction force of the vacuum is used. When the device moves along the inner wall of the hose from the tip of the suction hose toward the tank , in order to confirm the position of the moving device on the inner wall in turn, there is a lid for is attached with a rope for confirming the length sucked into the suction hose .

According to the present invention, while the suction hose is connected to the vacuum, the device is sucked or pumped to move along the inner wall of the suction hose, so that the soil clinging to the inner wall of the suction hose is removed. can be easily and reliably removed. Moreover, according to the present invention, it is possible to provide an instrument suitable for such a removal method.

1 is a schematic diagram illustrating an example of a suction drilling system; FIG. 4 is a flow chart showing an example of a method for removing soil in a hose. Fig. 2 is a schematic perspective view showing an example of a device for removing soil discharged from a hose; FIG. 4 shows the tool for removing soil discharged from the hose of FIG. 3, where (a) is a view seen from the tip side, and (b) is a cross-sectional view taken along line AA of (a). It is a figure for demonstrating the process of the method of removing the waste soil in a hose. It is a figure for demonstrating the process of the method of removing the waste soil in a hose.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to this. In addition, the drawings include parts expressed by appropriately changing the scale, such as enlarging or emphasizing a part. In some drawings, an XYZ coordinate system is used to describe directions in the drawings. In this XYZ coordinate system, the axial direction of the cylindrical shape (cylindrical portion 61) of the appliance main body 60, which will be described later, is defined as the Z direction. The Y direction is a direction perpendicular to the Z direction and corresponds to the vertical direction in FIG. The X direction is a direction perpendicular to both the Y direction and the Z direction.

The method according to the embodiment described below is a method for removing waste soil clinging to the inner wall of a suction hose by performing a suction excavation method using a suction excavation system. Therefore, prior to explaining the method for removing the soil clinging to the inner wall of the suction hose, first, the suction excavation system and the suction excavation method using the suction excavation system will be described. In the following explanation, the operator who carries out the suction excavation method using the suction excavation system and the worker who carries out the method of removing the soil clinging to the inner wall of the suction hose by this method are simply called "workers". It says.

FIG. 1 is a schematic diagram showing an example of a suction excavation system SYS used when carrying out the suction excavation method. As shown in FIG. 1, the suction excavation system SYS includes an attachment 10 for excavating soil G, a suction earth-discharging vehicle 20 for sucking the excavated earth and sand, and a suction hose 30 connecting the attachment 10 and the suction earth-discharging vehicle 20. and a crane 40 for suspending a part of the suction hose 30. The suction excavation system SYS excavates excavated earth and sand while discharging the excavated earth and sand by sucking the excavated earth and sand into the suction earth-discharging vehicle 20 through the hollow attachment 10 and the suction hose 30 .

The attachment 10 is formed in a cylindrical shape and is detachably attached to the tip of the suction hose 30 . The attachment 10 advances into the ground from its tip to excavate the soil G, and sucks excavated earth and sand from an opening at the tip.

The suction earth discharge vehicle 20 is configured by mounting a pressurization/decompression device (vacuum) 22 and a discharged earth storage tank 23 on a vehicle 21 . The suction earth-discharging vehicle 20 is connected to a suction hose 30 and sucks excavated earth and sand through the suction hose 30 during suction excavation. In addition, when the excavated hole H is backfilled after the suction excavation method is implemented, the suction excavator 20 discharges the stored excavated earth S (see FIG. 5(b)) to the excavated hole H through the suction hose 30. It has a configuration that can be pumped to.

The pressurization/decompression device 22 is connected to a suction hose 30 and generates a negative pressure for sucking excavated earth and sand (excavated earth) S. As shown in FIG. Further, when pumping the dumped soil S stored in the suction dumping vehicle 20, the pressurization/depressurization device 22 generates a positive pressure for pumping the stored dumped soil S out of the vehicle. The pressurization/decompression device 22 includes, for example, a vacuum pump and a compressor, both of which are not shown. The waste soil storage tank 23 is a container that is connected to the suction hose 30 and stores the waste soil S sucked and transferred by the pressurization/decompression device 22 . The suction hose 30 is a hose used for sucking excavated earth and sand, and is also used when pumping stored excavated earth and sand. The suction hose 30 is formed flexibly, and has strength and pressure resistance against earth and sand to be sucked and pressure-fed. The suction hose 30 is composed of, for example, a resin bellows tube having a metal wire, and has flexibility and a predetermined strength.

A crane 40 is used to hang the suction hose 30 as described above. By suspending the suction hose 30, the attachment 10 can be easily held and operated, and the burden on the operator during suction excavation can be reduced. It should be noted that the crane 40 is an optional component in the suction drilling system.

The operation of the suction excavation method is performed as follows, for example, using the above-described suction excavation system SYS. First, prior to suction excavation, the suction excavation system SYS is arranged at a location close to the soil G to be excavated. Although the suction hose 30 is arranged in a state of being suspended in the air, it may be arranged in a state of being grounded. In the suction excavation work in this case, the crane 40 becomes unnecessary.

Then, the operator sticks the attachment 10 vertically into the soil G to be excavated, and starts the suction excavation work. When the operator operates the attachment 10, the soil G is excavated by scraping off the soil inside the attachment 10. - 特許庁The earth and sand scraped and crushed by the attachment 10 are sucked from the suction port 10 a of the attachment 10 by the suction force of the pressurization/decompression device 22 . Although the suction force at this time is not particularly limited, it is desirable to set the air volume within the range of 20 m ³ /min to 40 m ³ /min and the pressure within the range of -13 kPa to -97 kPa. The reason why it is desirable to set the suction force as described above is as follows. If the air volume or pressure of the suction force is set smaller than the above set value, the earth and sand crushed by the attachment 10 cannot be sufficiently sucked and discharged by the pressurization/decompression device 22 . Conversely, if the air volume or pressure of the suction force is set higher than the above set value, a wasteful suction force exceeding the suction force required for crushing and sucking the earth and sand is generated, resulting in increased noise and energy consumption. This is because problems such as

The earth and sand scraped and crushed by the attachment 10 is transferred from the excavation hole H through the suction hose 30 to the waste soil storage tank 23 and stored in the waste soil storage tank 23 . In addition, the waste soil S stored in the waste soil storage tank 23 can be used as earth and sand for backfilling the excavation hole H after installation of the object.

In the suction excavation method described above, excavated earth and sand are removed by transferring them through the suction hose 30 , so the removed earth S gradually clings to the inner wall of the suction hose 30 . Therefore, it is necessary to remove the soil S clinging to the inner wall of the suction hose 30 . For a method of removing the waste soil S clinging to the inner wall of the suction hose 30 (simply referred to as "method for removing waste soil in the hose"), refer to FIGS. I will explain while

FIG. 2 is a flow chart showing an example of a method for removing soil in a hose. In the method for removing soil shown in FIG. 2, first, a device for removing soil in a hose is prepared (step S01). The tool 50 for removing soil in the hose prepared in step S01 is a dedicated tool used in the method for removing soil in the hose. FIG. 3 is a schematic perspective view showing an example of the tool 50 for removing soil from the hose. As shown in FIG. 3 , the hose-inside soil removal tool 50 includes a tool body (tool) 60 and a rope 70 .

FIG. 4 shows the device 50 for removing soil in the hose of FIG. It is a sectional view. The instrument main body 60 can be inserted into the suction hose 30 from its opening 30A (see FIG. 5A) in the axial direction (Z direction), and is sucked by the suction force and pressure generated by the pressurization/decompression device 22. It is formed so as to be movable inside the cleaning hose 30 . As shown in FIG. 4 , the instrument body 60 has a cylindrical portion 61 and a lid portion (lid) 62 .

The cylindrical portion 61 is large enough to come into contact with the inner wall 30I (see FIG. 5(b)) of the suction hose 30, and is formed in a cylindrical shape extending in the Z direction, as shown in FIG. 4(a). , has an outer diameter D slightly smaller than the inner diameter d of the suction hose 30 . In addition, the cylindrical portion 61 is formed such that a part of the tip portion (end portion on the +Z side) 61A is recessed in the -Z direction, and has a substantially trapezoidal shape that is convex in the +Z direction and has four convex shapes. It has parts 61a, 61b, 61c and 61d. The convex portions 61a and the like are provided at regular intervals along concentric circles around the axis of the cylindrical portion 61, respectively. In addition, the convex portion 61a and the like are slightly rounded in order to prevent the inner wall 30I of the suction hose 30 from being damaged when it is inserted into the suction hose 30 or moved inside the suction hose 30. shape.

By the way, as will be described later, when the tip portion (cylindrical portion 61 + end portion 61A on the Z side) 60a of the device main body 60 is inserted into the suction hose 30, it hits the waste soil S deposited and deposited on the inner wall 30I, It acts to scrape and remove this discharged soil S. Therefore, by configuring the tip end portion 61A of the cylindrical portion 61 with such a convex portion 61a, etc., the area contacting the discharged earth S is reduced compared to the cylindrical shape without the convex portion 61a. can be increased, and the discharged soil S can be removed by raking it out more effectively. In addition, since the distal end portion 61A of the cylindrical portion 61 is configured to have the convex portion 61a or the like, when the device body 60 rotates relative to the suction hose 30 while advancing in the suction hose 30, the convex portion 61A Since the corner portion 61e of the shaped portion 61a acts to scrape off the discharged soil S while rotating, even the hardened discharged soil S can be effectively removed.

It is optional whether or not the convex portion 61a or the like is provided at the tip portion 61A of the cylindrical portion 61. FIG. That is, the cylindrical portion 61 may have a cylindrical shape without the convex portion 61a. Further, the convex portion 61a and the like are not limited to the configuration described above, and various configurations can be applied. For example, the above-described convex portions 61a and the like each have a substantially trapezoidal shape and are provided integrally with the cylindrical portion 61, but instead of this, a convex component is provided at the tip portion of the cylindrical portion 61. It may be a mounting structure, a rounded shape, a semicircular or semielliptical shape, and the number of protrusions 61a and the like formed in the cylindrical portion 61. It may be 3 or less or 5 or more.

The lid portion (lid) 62 is in the shape of a disk having the same diameter as the inner diameter of the cylindrical portion 61 and is installed parallel to the XY plane. The lid portion 62 is provided so as to block the opening 61C of the cylindrical portion 61, and seals the opening 61C. Such a configuration of the lid portion 62 prevents pressure from leaking through the opening 61C when negative pressure or positive pressure is applied to the instrument body 60 inserted into the suction hose 30, thereby preventing the pressure from leaking through the opening 61C. It is possible to suck or pump the instrument body 60 in 30 . Note that the lid portion 62 is not limited to one that completely seals, and may have a through hole, a gap, or the like in a part thereof, as long as the device main body 60 described above can be sucked or pumped.

The lid portion 62 is arranged on the rear end side (the −Z direction side) of the cylindrical portion 61, but not from the rear end (−Z direction side) 61B of the cylindrical portion 61, but from the rear end 61B to the tip. It is provided at a position slightly separated in the direction (+Z direction). As a result, the rear end portion (−Z side end portion of the cylindrical portion 61) 60b of the instrument main body 60 is composed of the −Z side surface 62a of the lid portion 62 and the inner peripheral surface 61I of the cylindrical portion 61. A concave portion 63 is formed. A mounting portion 62b for mounting the rope 70 is provided on the −Z side surface 62a of the lid portion 62 . For example, as shown in FIG. 4(b), the attachment portion 62b has a ring-shaped configuration to which the end portion of the rope 70 is tied. Note that the lid portion 62 may be provided at the rear end 61B of the cylindrical portion 61 .

The instrument main body 60 is made of metal, and is manufactured by a method such as casting, welding, or cutting. It is produced by processes such as cutting and welding a disk-shaped member fitted inside the other end side. Note that the instrument body 60 is not limited to being made of metal, and may be made of resin, wood, ceramic, or the like.

The rope 70 is provided on the rear end side (−Z direction side) of the instrument main body 60 , and its +Z side end portion 71 is attached to the lid portion 62 . The rope 70 has a thickness that can be held by a machine or an operator, and has a predetermined tensile strength. Also, the length of the rope 70 is set longer than the length of the suction hose 30 . For this reason, when the method for removing soil in the hose is carried out, the operator holds the rope 70 in a stretched state, so that even if the device main body 60 moves inside the suction hose 30, the rear end of the rope 70 can be removed. The portion (−Z side end portion) 72 always protrudes from the suction hose 30 . Therefore, the operator measures the length of the rope 70 protruding outside the suction hose 30 while holding the rope 70 on the suction hose 30 side in a stretched state, and uses the measured value to determine the length of the rope 70 for suction. The length of rope 70 in hose 30 can be calculated. As a result, it is possible to grasp the position of the instrument main body 60 within the suction hose 30 . In addition, in order for the operator to easily grasp the position of the device main body 60 in the suction hose 30, a display indicating the distance from the +Z side end 71 of the rope 70 (for example, the end 71 display of the length from the distance, display of marks that differ according to the distance, etc.) may be provided. In this case, while the rope 70 on the side of the suction hose 30 is stretched, the operator reads the display on the surface of the rope 70 located at the tip of the suction hose 30 (the end on the −Z side) to perform suction. The position of the tool main body 60 in the application hose 30 can be grasped.

Returning to the description of the method for removing soil in the hose shown in the flowchart of FIG. Install (step S02). FIG. 5 is a diagram for explaining the steps of the method for removing the discharged soil in the hose. 5(a) to 5(c), the suction hose 30 and the waste soil storage tank 23 are shown in end views, and the waste soil removal tool 50 in the hose is shown in side views.

In step S02, the operator first removes the attachment 10 from the other end (tip) of the suction hose 30 while one end (base end) of the suction hose 30 is attached to the waste soil storage tank 23, and The hose 30 is stretched as much as possible. Next, the operator inserts the tool main body 60 from its tip 60a into the suction hose 30 in the +Z direction, and as shown in FIG. do.

Continuing from step S02, the rope attached to the rear part of the instrument main body (instrument) is held (step S03). In step S03, the operator holds the rope 70 so that the rope 70 on the suction hose 30 side is stretched. For example, at this time, the operator stretches the rope 70 and grips it so as to pull the rope 70 slightly.

Following step S03, by sucking or pumping from the pressurization/decompression device (vacuum) in the direction of the waste soil storage tank, the instrument body (instrument) is sequentially moved along the inner wall of the hose from the tip to the tank (step S04 ). In step S<b>04 , the pressurizing/depressurizing device 22 is used to suck the instrument main body 60 in the suction hose 30 . As a result, as shown in FIG. 5(b), the instrument body 60 of the tip end portion 30a of the suction hose 30 is sequentially moved toward the base end portion 30b of the suction hose 30 attached to the waste soil storage tank 23. Let At this time, the distal end portion 60a of the device body 60 acts to scrape out the soil S clinging to the inner wall 30I of the suction hose 30, and separates the soil S of the suction hose 30 from the inner wall 30I. The discharged soil S separated from the inner wall 30I is transferred to and stored in the discharged soil storage tank 23 by the suction force of the pressurization/decompression device 22 . In this way, the device main body 60 moves sequentially toward the base end portion 30b while removing the soil S clinging to the inner wall 30I of the suction hose 30, and the device main body 60 moves toward the base end portion 30b of the suction hose 30. Upon arrival, the removal of the soil S in the suction hose 30 is completed.

In step S04, the instrument main body 60 is moved in one direction from the distal end portion 30a to the proximal end portion 30b of the suction hose 30, but it may be moved in the opposite direction as appropriate during the movement process. That is, the device main body 60 may be temporarily moved from the proximal end portion 30b side of the suction hose 30 to the distal end portion 30a side. Such a reverse movement of the tool body 60 may be performed, for example, by pumping using the pressurizing/depressurizing device 22, or the worker may pull the rope 70 to - It may be performed by pulling in the Z direction. In this way, by temporarily moving the tool body 60 in the reverse direction, if there remains unremoved soil S that has not been completely removed by the tool body 60, the remaining soil S is removed from the rear end 61B of the cylindrical portion 61. In addition, by moving the tool body 60 in the forward direction again to allow the tool body 60 to pass through again, the soil S can be removed more reliably. When the tool body 60 moves in reverse, the concave portion 63 (see FIG. 4B) of the tool body 60 serves as a space for accumulating the discarded soil S separated from the inner wall 30I by the rear end 61B of the cylindrical portion 61. Become.

At the same time as step S04, the operator grasps how far the instrument main body (instrument) has been sucked by the sucked length of the rope (step S05). In step S05, for example, as shown in FIG. 5(c), the worker inserts the rope 70 into the suction hose 30 from the length of the rope 70 protruding outside the suction hose 30 while the rope 70 is stretched. By grasping the length of a certain rope 70, the current position of the device main body 60 within the suction hose 30 is confirmed.

Following step S04 and step S05, after removing the waste soil by suction, the device main body (device) is pressure-fed from the pressurization/decompression device (vacuum) of the suction earth discharge vehicle in the direction opposite to the direction of the waste soil storage tank ( step S06). FIG. 6 is an explanatory view of the process related to the method for removing soil in the hose, continued from FIG. In step S06, the connection between the suction hose 30 and the waste soil storage tank 23 is cut off, and with the suction hose 30 connected to the pressurization/decompression device 22, as shown in FIG. do. Then, the instrument main body 60 is taken out from the suction hose 30 . This completes the steps of the method for removing soil in the hose. In addition, in the above-described method for removing soil in a hose, it is optional whether or not the process of step S06 is performed in addition to the processes of steps S01 to S05. If step S06 is not performed, for example, the operator may pull the instrument main body 60 out of the suction hose 30 by pulling the rope 70 in the -Z direction after completing steps S01 to S05.

An example of the method for removing soil in the hose has been described above. Since the body 60 is sucked or pumped to move the device body 60 along the inner wall 30I of the suction hose 30, the soil S in the hose can be removed without removing the suction hose 30 from the pressurization/decompression device 22.例文帳に追加In addition, it is possible to easily and reliably remove the soil S adhering to the portions distant from the both ends 30a and 30b of the suction hose 30. In addition, when the method for removing the discharged soil in the hose is performed while sucking the device main body 60, the discharged soil S on the inner wall 30I of the suction hose 30 hits the device main body and is separated and removed from the inner wall 30I of the suction hose 30 as it is. Since the soil S is sucked and stored in the waste soil storage tank 23, there is no need to recover the peeled and removed waste soil S, and the waste soil S in the suction hose 30 can be easily removed. Further, according to the method having the step S06 in addition to the steps S01 to S05, after the soil removal work in the suction hose 30, the device body 60 can be easily pulled out from the suction hose 30 and recovered. can do.

In addition, the end portion 60a of the device main body 60 on the side of the waste soil storage tank 23 is rounded and has an uneven shape that does not damage the inner wall 30I of the suction hose 30, and the end portion 60b on the opposite side is There is a lid portion 62 for using the suction force of the pressurization/decompression device 22, and the lid portion 62 is provided for confirming the position on the inner wall 30I of the suction hose 30 where the instrument main body 60 that moves sequentially is located. , is attached with a rope 70 for checking the sucked length. As described above, since the device main body 60 has a configuration suitable for the above-described method for removing soil in the hose, the method for removing soil in the hose can be performed using the device 50 for removing soil in the hose including such a device body 60. By doing so, it is possible to easily and reliably remove the soil from the suction hose 30 .

Although the embodiment has been described above, the present invention is not limited to the above description, and various modifications can be made without departing from the gist of the present invention.

20... Suction earth-discharging vehicle 22... Pressurization/decompression device (vacuum)
23 … Waste soil storage tank (tank)
30... Suction hose 30I... Inner wall of suction hose 60... Instrument body (instrument)
62 Lid part (lid)
70... Rope H... Mining hole S... Unloading

Claims (3)

a suction dump truck equipped with a vacuum for sucking dumped soil and a tank for storing the dumped dumped soil;
a suction hose connected to the suction earth unloading vehicle from the mining hole;
A method for removing waste soil stuck to the inner wall of the suction hose by a suction excavation method using
A step of attaching a cylindrical device having a size that contacts the inner wall of the hose to the tip of the suction hose;
holding a rope attached to the rear of the device;
Thereafter, a step of moving the device along the inner wall of the hose from the tip to the tank by sucking or pumping from the vacuum in the direction of the tank;
At the same time, when the device and the rope attached to the device move from the tip of the suction hose toward the tank along the inner wall of the hose, the portion of the rope sucked into the suction hose is reduced. an operator ascertaining the position of the device within the suction hose from its length;
A method for removing waste soil clinging to the inner wall of a hose consisting of After removing the dumped soil by suction, pumping the device from the vacuum of the suction dumping vehicle in the direction opposite to the direction of the tank;
2. The method of claim 1, wherein A cylindrical instrument for use in the method of claim 1 or claim 2, comprising:
In the direction of the tank, it has an uneven shape so as not to damage the inner wall.
In the opposite direction, there is a lid for using the suction power of the vacuum,
The lid has
Sequentially, in order to confirm the position of the moving instrument on the inner wall, when the instrument moves from the tip of the suction hose toward the tank along the inner wall of the hose, suction is applied to the suction hose. A rope that allows you to check the inserted length is attached,
An instrument for removing soil stuck to the inner wall characterized by

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