JP5206363B2 - Sediment transport method and sediment transport system - Google Patents

Description

  The present invention constructs a tunnel using excavation means (for example, a shield machine) for excavating the tunnel and unloading means (for example, a belt conveyor or a mud pump) for carrying out the earth and sand excavated by the excavation means from the excavation site. In particular, in the case where the amount of earth and sand transported by the unloading means is less than the amount of sand and sand excavated by the means of excavation per unit time, the method for transporting earth and sand efficiently from the excavation site and the earth and sand using the method It relates to an unloading system.

  One of the shield methods for excavating the ground using a shield machine to construct a tunnel is to fill the earth pressure chamber in the shield machine with the excavated earth and sand, and counteract the face pressure and groundwater pressure, etc. There is a mud pressure shield method that stabilizes the face.

  In such a mud pressure shield method, when carrying out excavated earth and sand from the excavation site, slurry is prepared by mixing mud water with the excavated earth and sand, and the slurry is tunneled through a pipe by a mud pump. A method of pumping out to the outside of the machine and taking it out may be employed.

For example, Patent Document 1 discloses that in tunnel construction by a shield method, mud water is added to the excavated earth and sand to be slurried, and the mud is separated from the slurried earth and sand that has been carried out from the tunnel. A muddy water circulation system is disclosed in which the muddy water is supplied again to the excavation site and added to the excavated soil.
JP 2003-41884 A

  In order to slurry the excavated earth and sand so as to be carried out by the mud pump, it is usually necessary to add mud water several times the amount of earth and sand. In other words, the mud pump needs to transport a slurry having a volume many times larger than the amount of earth and sand excavated by the shield machine.

  Furthermore, if you want to increase the shield machine digging speed during tunnel construction faster than the original construction plan, the amount of earth and sand excavated will increase, and several times more mud will be added to the increase in the earth and sand. Therefore, the capacity of the slurry is increased, and the slurry cannot be carried out by the wastewater pump adopted by estimating the discharged amount of the slurry according to the initial construction plan.

As such a countermeasure, for example, it is conceivable to change to a sludge pump with improved discharge capacity, but a large sludge pump may not be installed in a tunnel with a small cross section due to dimensional restrictions.
Moreover, even if a large drainage pump can be installed in the tunnel, the construction cost will increase due to the increase in the size of the drainage pump, and the work space in the mine will be reduced, which may be disadvantageous in terms of ensuring safety. There is also.

  On the other hand, in the technique of the mud circulation system described in Patent Document 1, no countermeasure is particularly taken against such a problem.

  The present invention has been made in view of the above points. Excavation means (for example, a shield machine) for excavating a tunnel and unloading means (for example, a belt conveyor or the like) for unloading earth and sand excavated by the excavation means from the excavation site. When constructing a tunnel using a sludge pump), especially when the amount of sediment transported by the transporting means is less than the amount of sediment transported by the drilling means per unit time, the sediment is efficiently removed from the excavation site. An object is to provide a method for carrying out sediment and a sediment carrying system using the method.

In order to achieve the above-mentioned object, the present invention provides a method for constructing a tunnel using excavation means for excavating a tunnel and unloading means for unloading earth and sand excavated by the excavation means from a drilling site. In the case where the amount of earth and sand carried out by the carrying-out means is less than the amount of earth and sand excavated by the excavating means,
In the previous stage of the unloading means, the earth and sand excavated by the excavating means is temporarily stored, and earth and sand storage means for introducing the stored earth and sand into the unloading means,
The earth and sand stored in the earth and sand storage means are carried out by the carry-out means ,
As the unloading means, the earth and sand is introduced from the earth and sand storage means, and the earth and sand slurrying apparatus for preparing slurry by mixing muddy water into the introduced earth and sand, and the slurry produced by the earth and sand slurrying apparatus from the excavation site It is characterized by using a discharge mud pump .

According to the earth and sand carrying-out method of the present invention, even if the amount of earth and sand carried out by the carrying-out means is smaller than the amount of earth and sand excavated by the excavating means per unit time, the carrying-out means carries out during the excavation period. The earth and sand that cannot be stored can be temporarily stored in the earth and sand storage means, and the earth and sand that cannot be carried out by the carrying means during the excavation period can be carried out by the carrying means during the excavation suspension period. Sediment can be efficiently carried out from the excavation site without increasing.
In addition, compared to the method using Zuritro (a truck that transports and transports earth and sand) often used to carry out sediment excavated by the shield method, the track facilities can be simplified, so in a narrow mine Safety can be ensured.

  In the present invention, the unloading means includes at least a part of a digging period in which the tunnel is excavated by the excavating means and an excavation suspension period in which the excavating means does not excavate the tunnel in the tunnel construction process. The earth and sand stored in the earth and sand storage means may be carried out at least during a part of the period.

  Moreover, in this invention, it is good also as setting the said excavation stop period so that the said carrying-out means can carry out all the earth and sand stored in the said sediment storage means within the said excavation stop period. According to this configuration, it is possible to efficiently set the excavation suspension period for preventing the earth and sand from overflowing the earth and sand storage means.

  Moreover, in this invention, it is good also as setting the capacity | capacitance of the said earth and sand storage means so that the earth and sand excavated by the said excavation means at the end of the said excavation period can be stored. According to this configuration, the capacity of the earth and sand storage means for preventing the earth and sand from overflowing from the earth and sand storage means can be set efficiently.

  Further, in the present invention, a shield machine is used as the excavation means, a period for excavating a width corresponding to one ring of the segment by the shield machine is set as the excavation period, and the excavation pause period is set by the shield machine. A period for assembling one ring of the segments on the inner wall of the excavated tunnel may be set. According to this configuration, the earth and sand excavated by the shield machine and stored in the earth and sand storage means can be carried out by the carry-out means by effectively using the segment assembly period.

Further, the present invention comprises a drilling means for excavating a tunnel and an unloading means for carrying out the earth and sand excavated by the excavating means from the excavation site, and excavated by the excavating means per unit time when constructing the tunnel. The earth and sand carrying system is used when the amount of earth and sand carried by the carrying means is smaller than the amount of excavated earth and sand. The carrying means introduces the earth and sand from the earth and sand storage means and the introduced It has a soil and sand slurrying device that mixes mud water with the soil and makes a slurry, and a mud discharge pump that transports the slurry made by the soil and sand slurrying device from an excavation site. Means for temporarily storing the earth and sand excavated by the means and introducing the stored earth and sand into the carrying-out means; In the tunnel construction process, the earth and sand stored in the earth and sand storage means are carried out in both the excavation period in which the excavation means excavates the tunnel and the excavation suspension period in which the excavation means does not excavate the tunnel. And

According to the present invention, the drilling means for drilling a tunnel (e.g., shield machine) and, upon applying a tunnel using an unloading means to unload the sediment excavated by drilling means from the drilling site, in particular, the unit time When the amount of sediment transported by the unloading means is smaller than the amount of soil sedimented by the drilling means, it is possible to provide a sediment transporting method for efficiently transporting sediment from the excavation site and a sediment transport system using the same.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a diagram showing equipment used in the sediment transport method in the shield method according to the present embodiment.

  FIG. 1 shows a method for carrying out excavated earth and sand when the mud pressure shield method is used among the shield methods. The mud pressure type shield construction method is a construction method in which the earth pressure chamber in the shield machine is filled with excavated earth and sand, and the earth pressure is counteracted by the earth pressure and groundwater pressure to stabilize the face.

  As shown in FIG. 1, in the earth and sand carrying-out method according to this embodiment, the belt conveyor 12 for conveying the earth and sand excavated by the shield machine 10 to the rear of the face and the earth and sand transferred by the belt conveyor 12 are temporarily stored. The earth and sand stocking device 14 to be stored, the earth and sand stored in the earth and sand stocking device 14 were introduced, and the earth and sand slurrying device 16 for mixing slurry with the mud to prepare slurry, and the earth and sand slurrying device 16 were used. A sludge pump 18 that carries the slurry out of the tunnel 2 is used.

  Of these facilities, the earth and sand stocking device 14, the earth and sand slurrying device 16, and the mud pump 18 are mounted on, for example, a track rail 20 laid inside the tunnel 2 excavated during tunnel construction. A carriage 22 that is placed and can travel along the track rail 20 is provided in the lower part.

The belt conveyor 12 is for conveying the earth and sand excavated by the shield machine 10 to the earth and sand stock apparatus 14 provided on the track rail 20 behind the face.
The facility for transporting the earth and sand used here is not limited to the belt conveyor 12, and a screw conveyor may be used. In addition, when the earth and sand have fluidity, a pump of a pumping system may be used. Good. That is, any material can be used as long as it can transport the earth and sand excavated from the shield machine 10 to the earth and sand stocking device 14.

The earth and sand stocking device 14 may be any container that can temporarily store the earth and sand excavated by the shield machine 10. For example, an agitator hopper as shown in the figure can be used.
Here, the earth and sand stock apparatus 14 has a capacity capable of storing at least the earth and sand excavated at the end of the excavation period by the shield machine 10. The capacity of the earth and sand stocking device 14 is set by the excavation period, the amount of earth and sand excavated during the excavation period, and the amount of earth and sand carried out from the earth and sand stocking device 14.

  A feeder conveyor 15 is provided between the earth and sand stocking device 14 and the earth and sand slurrying device 16, and the earth and sand stored in the earth and sand stocking device 14 is introduced into the earth and sand slurrying device 16.

Further, inside the tunnel 2, a mud feeding pipe 24 for transferring the mud material from the outside of the tunnel 2 to the earth and sand slurrying device 16 is provided.
For example, muddy water or fresh water is used as the muddy material. Then, the amount of mud added at a predetermined magnification (for example, about 5 to 6 times) with respect to the amount of earth and sand introduced from the feeder conveyor 15 to the earth and sand slurrying device 16 is sludged into the earth and sand via the mud pipe 24. The device 16 is mixed.

  Further, the earth and sand slurrying device 16 is provided with a stirrer 17, and the earth and sand and the mud material introduced into the earth and sand slurrying device 16 are mixed and stirred into a slurry.

  As the mud pump 18, for example, a pump for pumping concrete or mortar can be used. The mud pump 18 is connected to a mud pipe 26 piped from the outside of the tunnel 2, and the slurry pumped by the mud pump 18 is carried out of the tunnel 2 through the mud pipe 26.

  The slurry carried out of the tunnel 2 is transferred to, for example, a muddy water treatment plant 28 installed outside the tunnel 2 and separated into muddy water and earth and sand. The separated earth and sand are disposed of as general residual soil. On the other hand, the separated muddy water is transferred again by the mud pump 30 through the mud pipe 24 to the earth and sand slurry device inside the tunnel 2 and mixed with the earth and sand for use.

The earth and sand carrying-out method according to the present embodiment is particularly effective when the earth and sand excavated by the shield machine 10 cannot be carried out only by using the earth and sand slurrying device 16 and the mud pump 18 among the above facilities.
That is, since the amount of earth and sand excavated during the excavation period of the shield machine 10 is large, when the earth and sand excavated by the shield machine 10 is directly input to the earth and sand slurrying device 16, a mud is added to the earth and sand. This is a case where the amount of the slurry increased by the amount exceeds the amount that can be carried out by the mud pump 18 during the excavation period. In this case, the slurry produced by the earth and sand slurrying apparatus 16 overflows from the earth and sand slurrying apparatus 16.

  Therefore, in the present embodiment, the earth and sand stocking device 14 is used together with the earth and sand slurrying device 16 and the mud pump 18 to carry out the earth and sand.

2A and 2B are diagrams for explaining the sediment transport method according to the present embodiment, in which FIG. 2A shows the excavation period and FIG. 2B shows the excavation suspension period.
The excavation period here refers to, for example, a period in which the width of one ring of the segment 4 installed on the inner wall of the tunnel 2 excavated by the shield machine 10 as a tunnel lining body is excavated, and the excavation pause period Means a period for assembling the segment 4 after excavating the width of the segment 4 for one ring.

  As shown in FIG. 2 (a), in the sediment transport method according to the present embodiment, all the sediment excavated by the shield machine 10 during the excavation period is once transferred to the sediment stock apparatus 14 by the belt conveyor 12, and thereafter The earth and sand are conveyed from the earth and sand stocking device 14 to the earth and sand slurrying device 16 by the feeder conveyor 15. At this time, the amount of earth and sand transported by the feeder conveyor 15 is adjusted so that the slurry produced by the earth and sand slurrying device 16 is carried out by the mud pump 18 without overflowing from the earth and sand slurrying device 16.

  Here, during the excavation period, the amount of earth and sand to be excavated by the shield machine 10 is larger than the amount of earth and sand transported from the earth and sand stock device 14 to the earth and sand slurrying device 16. The amount of earth and sand increases.

In addition, as shown in FIG. 2B, during the excavation suspension period, as in the excavation period, the earth and sand are conveyed from the earth and sand stock device 14 to the earth and sand slurrying device 16 by the feeder conveyor 15, and the earth and sand slurrying device. The slurry produced in 16 is carried out by the mud pump 18.
As a result, the amount of earth and sand stored in the earth and sand stocking device 14 during the excavation period decreases.

  Here, the excavation suspension period is set so that all of the earth and sand stored in the earth and sand stocking device 14 is conveyed within that period. By doing in this way, when excavation is restarted in the state where the earth and sand stored in the earth and sand stocking device 14 remains, the amount of earth and sand in the earth and sand stocking device 14 increases while repeating the excavation period and the excavation pause period. The earth and sand can be prevented from overflowing from the earth and sand stocking apparatus 14.

  In addition, it should be noted that the earth and sand stock device 14 has a capacity to store at least the excavated earth and sand at the end of the excavation period. That is, the volume that can store the amount of earth and sand excavated by the shield machine 10 during the excavation period minus the amount conveyed from the earth and sand stock device 14 to the earth and sand slurrying device 16 during the excavation period, What is necessary is just to have the apparatus 14. FIG.

  By transporting the earth and sand excavated by the shield machine 10 as described above, the excavated earth and sand can be efficiently and smoothly carried out of the tunnel 2.

Next, the case where the earth and sand excavated by the shield machine 10 is carried out without using the earth and sand stock apparatus 14 (case 1), and the case where the earth and sand stock apparatus 14 is carried out as in the present embodiment (case 2). As for numerical values, a specific numerical value is set, and the numerical value of the excavation speed, the excavation period, and the excavation suspension period is obtained and compared. The details will be described below.
In addition, as another comparative example, when carrying out the earth and sand without using the earth and sand stocking device 14, a numerical experiment was performed when the mud pump 18 with improved discharge capacity was used (case 3).

  FIG. 3 is a diagram for explaining the conditions used in the numerical experiment.

  As shown in FIG. 3, the tunnel 2 having a diameter of 4 m is excavated by 1 m which is the width of one ring of the segment 4 by the shield machine 10, and the excavated earth and sand is about five times (sand: mud water = 16.5: 83.5) The volume of muddy water was mixed to produce a slurry, and when the slurry was carried out by the mud pump 18, numerical experiments were conducted for cases 1 to 3 above.

In case 1, the excavated earth and sand is directly transferred to the earth and sand slurrying apparatus 16 without using the earth and sand stocking apparatus 14, and is slurried by the earth and sand slurrying apparatus 16 and is provided with a discharge amount of 2 m ³ / min. 18 was used to carry out the slurry in the sediment slurrying apparatus 16.

In case 2, the excavated earth and sand are first transferred to the earth and sand stocking device 14, and then gradually transferred from the earth and sand stocking device 14 to the earth and sand slurrying device 16 by the feeder conveyor 15 and slurried by the earth and sand slurrying device 16. Thus, the slurry in the earth and sand slurrying device 16 is carried out by using the mud pump 18 having a carry-out amount of 2 m ³ / min.

In case 3, the excavated earth and sand are directly transferred to the earth and sand slurrying apparatus 16 without using the earth and sand stocking apparatus 14, and are slurried by the earth and sand slurrying apparatus 16 to provide a discharge mud pump having a discharge amount of 4 m ³ / min. 18 was used to carry out the slurry in the sediment slurrying apparatus 16.

  In each case, it took 35 minutes to assemble the segment 4 after excavation by the shield machine 10, and this time was set as the excavation suspension period.

Under such conditions, first, the amount of earth and sand excavated by the shield machine 10 corresponds to the amount of tunnel 1 having a diameter of 4 m (= 2 m radius) that has been excavated by 1 m, which is one ring of the segment 4. As shown in Fig. 1, approximately 13 m ^{3 is} generated.
π × (2 (m)) ² × 1 m≈13 (m ³ ) (Formula 1)

Further, the slurry is mixed with muddy water having a volume about 5 times that of the earth (sand: mud water = 16.5: 83.5), so that about 80 m ^{3 is} generated as shown in Equation 2.
13 (m ³ ) /16.5×100≈80 (m ³ ) (Formula 2)

  FIG. 4 is a table summarizing the excavation speed, excavation period, excavation suspension period, time required for excavation and segment assembly, and the like for each case.

As shown in FIG. 4, in case 1, it takes 40 minutes as shown in Equation 3 to carry out the slurry generated in about 80 m ³ by the mud pump 18 having a carry-out amount of 2 m ³ / min.
80 (m ³ ) / 2 (m ³ / min) = 40 (min) (Formula 3)
Therefore, in case 1, since the excavated earth and sand are directly transferred to the earth and sand slurrying apparatus 16 without using the earth and sand stocking apparatus 14, in order to prevent the slurry from overflowing from the earth and sand slurrying apparatus 16, the shield machine 10 It is necessary to limit the excavation speed to 2.5 cm / min as shown in Equation 4.
1 (m) / 40 (min) = 2.5 (cm / min) (Formula 4)

  In addition, since the segment assembly time is 35 minutes after excavation, the time required for one cycle of excavation and segment assembly is 75 minutes (excavation time 40 minutes + segment assembly time 35 minutes).

On the other hand, in the case 2 (the earth and sand carrying-out method according to the present embodiment), the slurry generated about 80 m ³ is carried out by the mud pump 18 having a carrying-out amount of 2 m ³ / min as in the case 1. Therefore, it takes 40 minutes to carry out all the slurry from the inside of the tunnel 2 as in the case 1.
However, in case 2, the earth and sand that cannot be carried out during the excavation period can be stored in the earth and sand stocking device 14. Thereby, the excavation speed of the shield machine 10 can be increased compared to the case 1.
For example, when the excavation speed of the shield machine 10 is 5.0 cm / min, the excavation period is shortened to half that of Case 1 to 20 minutes, but since the subsequent segment assembly time is 35 minutes, the next excavation resumes. A total of 55 minutes can be applied to the period during which the sludge pump 18 carries the slurry out of the sediment slurrying device 16. On the other hand, in case 2, it takes only 40 minutes to carry out all the slurry from the inside of the tunnel 2 as in the case 1, so that a period necessary for carrying out is sufficient.

In addition, when the excavation speed is set to 5.0 cm / min, since 20 minutes have passed since the excavation started at the end of the excavation period, 40 m ³ , which is half of 80 m ³ , from the mud pump 18. The slurry has already been discharged. Nachi Suwa, is 6.5m ³ is the amount of half of 13m ³ in terms of sediment volume is unloaded, so that the remaining 6.5m ³ are stored in the sediment collecting assembly 14.
Therefore, what is necessary is just to ensure the volume which accommodates the earth and sand of the earth and sand stock apparatus 14 at least 6.5 m < ³ >.

Further, in case 3, since about 80 m ³ of the slurry obtained by Equation 2 is carried out by the mud pump 18 having a carry-out amount of 4 m ³ / min, the time required for discharging is 20 minutes as shown in Equation 5. Take it.
80 (m ³ ) / 4 (m ³ / min) = 20 (min) (Formula 5)
Therefore, the excavation speed of the shield machine 10 at this time can be increased to 5.0 cm / min as shown in Equation 6.
1 (m) / 40 (min) = 5.0 (cm / min) (Formula 6)

  Even in case 3, since the segment assembly time after excavation takes 35 minutes, the time required for one cycle of excavation and segment assembly is 55 minutes (excavation time 20 minutes + segment assembly time 35 minutes).

However, in the case 3, if the discharge capacity of the mud pump 18 is improved, the size of the tunnel 2 is increased. Therefore, the tunnel 2 having a small cross section may be unable to be installed because the size of equipment that can be installed in the mine is limited.
Moreover, even if the large-scale mud pump 18 can be installed inside the tunnel 2, the construction cost due to the use of the large-scale mud pump 18 increases, and the working space in the mine is narrowed to ensure safety. Can be disadvantageous.

As described above, in the sediment transport method according to the present embodiment, the sediment excavated by the shield machine 10 is temporarily stored in the previous stage of the sediment stock device 14, and the stored sediment is stored in the sediment slurrying device 16. The sediment stock apparatus 14 to be introduced is provided, and the slurry produced by mixing mud water with the sediment in the sediment stock apparatus 14 is carried out by the mud pump 18.
Here, in the construction process of the tunnel 2, the mud pump 18 includes at least a part of the excavation period during which the tunnel 2 is excavated by the shield machine 10 and the excavation suspension period during which the tunnel 2 is not excavated by the shield machine 10. The slurry is unloaded at least during some period.

  Thereby, even if the amount of earth and sand carried out by the earth and sand slurrying device 16 and the mud pump 18 is smaller than the amount of earth and sand excavated by the shield machine 10, it cannot be carried out by the mud pump 18 within the excavation period. The earth and sand corresponding to the amount of the slurry can be stored in the earth and sand stocking device 14, and the earth and sand corresponding to the amount of the slurry that could not be carried out by the mud pump 18 during the excavation period can be stored in the earth and sand slurry. Therefore, the sediment can be efficiently carried out from the inside of the tunnel 2 without increasing the carry-out amount of the mud pump 18.

  Moreover, according to the earth and sand carrying-out method which concerns on this embodiment, it is possible to carry out this slurry, when the mud pump 18 slurries all the earth and sand stored in the earth and sand stock apparatus 14 within the excavation suspension period. By setting the excavation suspension period, it is possible to efficiently set the excavation suspension period for preventing sediment from overflowing from the sediment storage device 14.

  Moreover, according to the earth and sand carrying-out method which concerns on this embodiment, by setting the capacity | capacitance of the earth and sand stock apparatus 14 so that the earth and sand excavated by the shield machine 10 can be stored at the end of the excavation period, It is possible to efficiently set a capacity for preventing overflow.

It is a figure which shows the equipment used for the earth and sand carrying-out method in the shield construction method based on this embodiment. It is a figure for demonstrating the earth and sand carrying-out method which concerns on this embodiment, the figure (a) shows during a digging period, and the figure (b) shows during a digging suspension period. It is a figure which shows the conditions used for the numerical experiment. For each case, the excavation speed, excavation period, excavation suspension period, time required for excavation and segment assembly, etc. are summarized in a table.

Explanation of symbols

2 Tunnel 4 Segment 10 Shield Machine 12 Belt Conveyor 14 Sediment Stock Equipment 15 Feeder Conveyor 16 Sediment Slurry 17 Stirrer 18 Mud Pump 20 Track Rail 22 Dolly 24 Mud Pipe 26 Mud Pipe 28 Mud Treatment Plant 30 Mud Pump

Claims (6)

Excavation amount of earth and sand excavated by the excavating means per unit time when constructing the tunnel using excavating means for excavating the tunnel and unloading means for carrying out the earth and sand excavated by the excavating means from the excavation site More, a method for carrying out earth and sand when the amount of earth and sand carried out by the carrying-out means is small,
In the previous stage of the unloading means, the earth and sand excavated by the excavating means is temporarily stored, and earth and sand storage means for introducing the stored earth and sand into the unloading means,
The earth and sand stored in the earth and sand storage means are carried out by the carry-out means ,
As the unloading means, the earth and sand is introduced from the earth and sand storage means, and the earth and sand slurrying apparatus for preparing slurry by mixing muddy water into the introduced earth and sand, and the slurry produced by the earth and sand slurrying apparatus from the excavation site A method for carrying out earth and sand, characterized by using an unloading mud pump .   In the tunnel construction process, the unloading means includes at least a part of a digging period in which the digging means digs a tunnel, and at least a part of a digging suspension period in which the digging means does not dig a tunnel; The method according to claim 1, wherein the earth and sand stored in the earth and sand storage means are carried out.   The sediment excavation period according to claim 2, wherein the excavation suspension period is set so that the unloading means can carry out all of the sediment stored in the sediment storage means within the excavation suspension period.   4. The sediment transport method according to claim 2, wherein a capacity of the sediment storage means is set so that sediment excavated by the excavation means can be stored at the end of the excavation period. As the excavation means, using a shield machine,
As the excavation period, set a period for excavating the width of one ring of the segment by the shield machine,
The earth and sand carrying-out method according to any one of claims 2 to 4, wherein a period for assembling one ring of the segments on the inner wall of the tunnel excavated by the shield machine is set as the excavation suspension period. An excavation means for excavating a tunnel, and an unloading means for carrying out the earth and sand excavated by the excavation means from an excavation site. More, a sediment transport system used when the transport amount of sediment by the transport means is small,
The unloading means introduces the earth and sand from the earth and sand storage means, and mixes the introduced earth and sand with muddy water to produce a slurry, and the slurry produced by the earth and sand slurrying apparatus from the excavation site. A mud pump to carry out,
In the front stage of the unloading means, the earth and sand excavated by the excavation means is temporarily stored, and the earth and sand storage means for introducing the stored earth and sand into the unloading means,
The earth and sand carrying-out system, wherein the carrying-out means carries out the earth and sand stored in the earth and sand storage means.

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