JP2009243221A - Shield machine, and starting method and arrival method therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a shield machine which facilitates linear control in tunnel excavation and which does not damage natural ground at its start, and a starting method therefor. <P>SOLUTION: The shield machine 1 advances into the natural ground 13, while a slope 19 is excavated by cutter heads 10 of upper and lower cutter portions 2 and 3. Earth covering thickness in the advance of the shield machine 1 into the natural ground 13 is set 0.3 times as large in dimension as the height H of the shield machine 1. Thus, since the self-weight of an earthfill section is greater in magnitude than a frictional force which is generated between the natural ground 13 and the shield machine 1 along with the advance of the shield machine 1 into the natural ground 13, the earthfill section is prevented from swelling by being pulled in the penetration direction of the shield machine 1. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a shield machine, a start method and a reach method of a shield machine.

  With regard to a shield machine that underpasses a road or the like, the present applicant, for example, in Patent Document 1, combines a plurality of main shields that can be moved forward and backward independently from each other in a predetermined arrangement, and independently separates the main shields. The shield machine which excavates and excavates the natural ground is disclosed. When excavating a tunnel with this shield machine, first, the main shield located outside the uppermost stage of the plurality of main shields is dug first, and then the main shield located inside is dug up to the top. Project all the upper main shield, and then dig the lower main shield.

Patent Document 2 discloses a method of propelling a shield machine in which a cutter part is divided into an upper stage and a lower stage in a state where the upper cutter part protrudes in a traveling direction from the lower cutter part. . In this method, the shield machine is installed in a state where the upper part of the lower cutter part is exposed above the ground surface in a state where the shield machine is tilted. Excavate the earth retaining wall, and then excavate the natural ground while excavating the natural ground with the upper and lower cutters.
JP 2006-46061 A JP 2006-207141 A

  However, in the shield machine described in Patent Document 1, since a propulsion device such as a jack and a soil removal device such as a screw conveyor are installed for each of the plurality of main shields, the weight of the front part of the shield machine becomes heavy. Therefore, linear control during propulsion is difficult. In addition, when excavating a small earth covering section, since the earth covering is shallow, if there is a slight deviation in linear control, it will affect the ground immediately.

  Moreover, in the propulsion method of the shield machine described in Patent Document 2, there is almost no cover thickness when the upper cutter portion of the shield machine enters the ground. Therefore, since the weight of the earth covering portion is smaller than the friction force generated between the ground and the shield machine as the shield machine enters the ground, the upper cutter part of the shield machine enters the ground. At that time, the earth covering portion is pulled in the traveling direction of the shield machine and rises, and the ground is damaged.

  Therefore, the present invention has been made in view of the conventional problems as described above, and is easy to linearly control when excavating a tunnel, and a shield machine that does not damage natural ground when starting or reaching, An object of the present invention is to provide a starting method and a reaching method for a shield machine.

  In order to achieve the above object, a shield machine according to the present invention is a shield machine for digging in a natural mountain, and cutter parts that can be driven independently from each other are arranged in an upper stage and a lower stage at the front part of the shield machine. The upper and lower cutter portions are arranged such that the upper cutter portion protrudes in the advancing direction from the lower cutter portion (first invention).

  According to the shield machine of the present invention, the upper cutter part is fixedly arranged so as to protrude in the advancing direction from the lower cutter part, so that the excavation target section is divided into an upper part and a lower part for excavation. Can do. Moreover, since the remaining section is excavated by the lower cutter part while supporting the earth covering part by the preceding upper cutter part, the influence on the earth covering part by excavation can be eliminated. Therefore, compared to full-section excavation that excavates the entire cross-section of the excavation object at the same time, there is no possibility of ground deformation even when excavating the ground with a small covering. As a result, it is not necessary to carry out countermeasure work for ground deformation such as ground improvement on the small covering portion, so that the construction period can be shortened and the construction cost can be reduced.

  Furthermore, since the upper cutter unit and the lower cutter unit are fixed, a driving device or the like for moving these cutter units forward or backward independently is unnecessary. Since only a simple mechanism such as a driving device for rotating the cutter is provided, the weight of the front part of the shield machine can be reduced as compared with the conventional shield machine. Therefore, linear control during propulsion is facilitated and the tunnel can be excavated accurately. Moreover, since the number of devices in the shield machine main body is small, the capital investment cost of the shield machine main body can be reduced.

According to a second invention, in the first invention, each of the upper cutter unit and the lower cutter unit includes a plurality of cutters.
According to the shield machine by this invention, since each cutter part is provided with the some cutter, respectively, it can respond to the tunnel of various excavation cross-sectional shapes and magnitude | sizes by the combination of these cutters.

  The starting method of the shield machine according to the third aspect of the invention is that the upper and lower cutter parts are arranged at the front part of the shield machine and can be driven independently from each other. Install the shield machine fixedly arranged so that it protrudes in the traveling direction from the lower cutter part in the hole where the slope is formed in the traveling direction, propel the shield machine toward the slope, and It is characterized by entering the natural ground while excavating the slope.

  According to the start method of the shield machine according to the present invention, in the traveling direction, the start is made from a hole in which a slope made of natural ground is formed, and the slope is made to enter the natural ground while excavating the slope. It is possible to enter the natural ground in a shorter time than when excavating the earth retaining wall constructed by the above.

  Moreover, since the upper cutter part of the shield machine is fixedly arranged so as to protrude in the advancing direction from the lower cutter part, the slope can be divided into an upper stage and a lower stage for excavation. And since the remaining cross section is excavated by the lower cutter part while supporting the earth covering part by the upper cutter part, the influence on the earth covering part by excavation can be eliminated. Therefore, there is no possibility that the ground deformation of the covering portion will occur.

  Furthermore, by assembling the shield machine in the hole, the side surface of the hole can serve as a soundproof wall, and noise generated when the shield machine is assembled can be reduced.

  According to a fourth aspect of the present invention, in the third aspect, the thickness of the earth covering when the shield machine excavates the slope and enters the ground is 0.3 times or more the height of the shield machine. It is characterized by.

  According to the start method of the shield machine according to the present invention, since the earth covering thickness when the shield machine enters the ground is 0.3 times or more the height of the shield machine, the shield machine enters the ground. Along with this, the weight of the soil covering portion becomes larger than the friction force generated between the ground and the shield machine. Therefore, the earth covering portion is not pulled up in the approach direction of the shield machine, and does not rise.

  According to a fifth aspect of the shield machine reaching method, cutter parts that can be driven independently from each other are arranged in the upper stage and the lower stage at the front part of the shield machine, and the upper and lower cutter parts are the upper cutter part. When the shield machine, which is fixedly arranged so as to protrude in the direction of travel from the lower cutter part, reaches the hole where the slope is formed from the ground, the shield machine is propelled toward the slope. The slope is made to reach the hole while excavating the slope.

  According to the shield machine reaching method according to the present invention, when the shield machine is made to reach the hole where the slope made of the natural ground is formed from within the natural ground, the slope is made to enter the hole while excavating the slope, Thus, it is possible to enter the hole in a shorter time than when excavating a retaining wall constructed of concrete or the like.

  Moreover, since the upper cutter part of the shield machine is fixedly arranged so as to protrude in the advancing direction from the lower cutter part, the slope can be divided into an upper stage and a lower stage for excavation. And since the remaining cross section is excavated by the lower cutter part while supporting the earth covering part by the upper cutter part, the influence on the earth covering part by excavation can be eliminated. Therefore, there is no possibility that the ground deformation of the covering portion will occur.

  Further, by disassembling the shield machine in the hole after reaching the hole, the side surface of the hole can be used as a soundproof wall, and noise generated when the shield machine is disassembled can be reduced.

  According to a sixth invention, in the fifth invention, the covering thickness when the shield machine reaches the hole by excavating the slope is 0.3 times or more the height of the shield machine. It is characterized by.

  According to the shield machine arrival method of the present invention, since the earth covering thickness when the shield machine reaches the hole from the ground is 0.3 times or more the height of the shield machine, the shield machine reaches the hole. Along with this, the weight of the soil covering part becomes larger than the frictional force generated between the ground and the shield machine. Therefore, the earth covering part is not pulled up in the propulsion direction of the shield machine.

  According to the shield machine, the start method and the reach method of the shield machine of the present invention, linear control when excavating a tunnel is facilitated, and the ground is not damaged when starting or reaching.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.
1 and 2 are a front view and a side sectional view, respectively, of a shield machine 1 according to an embodiment of the present invention.

  As shown in FIGS. 1 and 2, the shield machine 1 includes a hood part 4 provided with cutter parts 2 and 3 that can be driven independently from each other, and a shield for propelling the shield machine 1 main body. It comprises a girder portion 6 having a jack 5 and the like, and a tail portion 9 having an erector 8 and the like for assembling the segment 7.

  The upper cutter unit 2 and the lower cutter unit 3 are provided on the front surface of the shield machine 1 main body, and include a cutter head 10 for excavating the natural ground 13 and a drive source 11 for rotating the cutter head 10. The cutter units 2 and 3 can be driven independently.

  The upper cutter unit 2 is arranged in the main body of the shield machine 1 so as to protrude by a predetermined length in the traveling direction from the lower cutter unit 3. Note that the protruding length is a value that varies depending on geological conditions and the like, and is appropriately determined for each site by design or the like.

  Each of the cutter units 2 and 3 includes a plurality of cutter heads 10, and three each are provided in the present embodiment. The appropriate number of cutter heads 10 is changed according to the shape, size, etc. of the cross section to be excavated.

  The girder unit 6 is provided with a shield jack 5 for propelling the shield machine 1 main body, a screw conveyor 12 for discharging earth and sand excavated by the cutter units 2 and 3 and the like.

  The tail part 9 is provided with an erector 8 and the like. By this erector 8, the segments 7 are sequentially assembled on the inner surface of the excavated tunnel 22, and the inner wall is constructed.

  Next, the result of examining the settlement amount of the natural ground 13 when excavating the tunnel 22 with the shield machine 1 described above using the finite element method will be described.

FIG. 3 is a diagram illustrating a two-dimensional analysis model of the natural ground 13 to be excavated.
As shown in FIG. 3, the natural ground 13 to be excavated has a geological structure composed of an asphalt layer 14, a sandy soil layer 16, and a gravel layer 17 from the ground surface toward the deep part. The geological conditions of each layer are shown below.

The thickness, Young's modulus, Poisson's ratio, unit volume weight, and static earth pressure coefficient of the asphalt layer 14 were 0.75 m, 600 MPa, 0.25, 14.7 kN / m ³ , and 0.5, respectively.

The thickness, N value, Young's modulus, Poisson's ratio, unit volume weight, static earth pressure coefficient, adhesive strength, and internal friction angle of the sandy soil layer 16 are 6.00 m, 10, 60 MPa, 0.3, and 18. It was set to 6 kN / m ³ , 0.5, 10 kPa, and 30 °.

The thickness, N value, Young's modulus, Poisson's ratio, unit volume weight, static earth pressure coefficient, adhesive force, and internal friction angle of the gravel layer 17 are 10.70 m, 50, 60 MPa, 0.3, 19.6 kN / m ³ , 0.5, 10 kPa, and 40 ° were set.

  First, when a sandy soil layer 16 having a depth of 3.0 m to 11.25 m is excavated with a shield machine A to D (described later) having a height of 8.25 m, that is, the soil covering thickness is The amount of settlement in the case of approximately 0.3 (= 3.0 m / 8.25 m) times the height of the shield machines A to D was analyzed by a two-dimensional finite element method. The analysis was performed for each of the cases where excavation was performed by three different excavation methods.

  4-6 is a figure which respectively shows the excavation method of the natural ground 13 in analysis case (a)-(c).

  In the analysis case (a), as shown in FIG. 4, the entire section excavation is performed by excavating the entire section to be excavated at the same time. Specifically, the analysis was performed for the case where the entire cross-section excavation was performed using the shield machine A whose height and width were 8.25 m and 10.5 m, respectively.

  In the analysis case (b), as shown in FIG. 5, the upper and lower sides of the shield machine 1 having the above-described configuration are excavated in a state where the upper cutter part 2 protrudes 1.0 m in the traveling direction from the lower cutter part 3. This is the case by step excavation. Specifically, the height and width are the same as those of the shield machine A, and the heights of the upper cutter unit 2 and the lower cutter unit 3 are 3.3 m and 4.95 m, respectively. An analysis was performed for a case where excavation was performed using a shield machine B having a difference between the tip and the tip of the lower cutter portion 3 of 1.0 m.

  In the analysis case (c), as shown in FIG. 6, the upper and lower sides where the upper cutter part 2 of the shield machine 1 having the above-described configuration is excavated in a state of protruding 0.5 m from the lower cutter part 3 in the advancing direction. This is the case by step excavation. Specifically, the height and width are the same as those of the shield machine A, and the heights of the upper cutter unit 2 and the lower cutter unit 3 are the same as those of the shield machine B, and the tip of the upper cutter unit 2 is An analysis was performed on the case where the upper and lower steps were excavated using the shield machine C whose difference from the tip of the lower cutter unit 3 was 0.5 m.

Next, the analysis result of the subsidence amount of the natural ground 13 by analysis case (a)-(c) is shown.
FIG. 7 is a diagram showing an analysis result of the settlement amount by excavation of the entire cross section of the analysis case (a).

As shown in FIG. 7, the maximum subsidence when the entire cross section was excavated simultaneously was 2.78 mm.
FIG. 8 is a diagram illustrating an analysis result of a settlement amount by excavation of the upper and lower steps where the preceding amount of the upper cutter unit 2 in the analysis case (b) is 1.0 m.
As shown in FIG. 8, the maximum subsidence amount when excavating with an upper and lower step provided by setting the leading amount of the upper cutter portion 2 to 1.0 m was 1.42 mm.
Although not shown, the maximum subsidence amount by excavation of the upper and lower steps was 2.34 mm when the preceding amount of the upper cutter unit 2 in the analysis case (c) was 0.5 m.

  From the above-described analysis result by the two-dimensional finite element method, it can be seen that when excavating with the upper and lower steps, the amount of settlement is smaller than when excavating the entire cross section simultaneously. In addition, it can be seen that the amount of settlement becomes smaller when the preceding amount of the upper cutter portion 2 is 1.0 m than when the preceding amount is 0.5 m.

  Next, in the same manner as described above, the subsidence amount of both layers when the depth of the natural ground 13 was excavated from 3.0 m to 11.25 m was analyzed by a three-dimensional finite element method. The analysis was performed for each case where excavation was performed by two different excavation methods.

  FIG. 9 is a diagram illustrating a three-dimensional analysis model of the natural ground 13. As shown in FIG. 9, the geological structure of the natural ground 13 is the same as the geological structure and geological conditions of the two-dimensional analytical model.

10 and 11 are diagrams showing a method for excavating the natural ground 13 in analysis cases (d) and (e), respectively.
In the analysis case (d), as shown in FIG. 10, the entire cross section excavation using the shield machine A was used.
In the analysis case (e), as shown in FIG. 11, the upper and lower steps excavation using the shield machine B was used. The upper and lower step excavation was analyzed only in the case where the upper cutter portion 2 was preceded by 1.0 m ahead of the lower cutter portion 3 from the analysis result by the above-described two-dimensional finite element method.

Next, the analysis result of the subsidence amount of the natural ground 13 by the analysis cases (d) and (e) is shown.
FIG. 12 is an enlarged cross-sectional view of one side of the excavation cross section, showing an analysis result of the amount of settlement by the entire cross section excavation of the analysis case (d).
As shown in FIG. 12, when the entire cross section was excavated simultaneously, the settlement occurred over a wide range on the side of the face. Specifically, the maximum sinking amount was 1.64 mm.

FIG. 13 is a cross-sectional view showing an analysis result of a subsidence amount by excavation of the upper and lower steps of the analysis case (e) and enlarging one side of the excavation cross section.
As shown in FIG. 13, the subsidence when excavating with a step difference occurred only in a narrow area on the side of the face. Specifically, the maximum sinking amount was 0.56 mm.

From the analysis result by the above-described three-dimensional finite element method, it can be seen that the subsidence amount is smaller when excavating with upper and lower steps than when excavating the entire cross section.
In addition, when excavating the upper and lower steps, the subsidence of the earth covering portion can be suppressed even when the earth covering thickness condition is severe that the earth covering thickness is approximately 0.3 times the height of the shield machines A to D. It can be seen that if the earth covering thickness is 0.3 times or more the height of the shield machines A to D, the settlement of the earth covering portion can be sufficiently suppressed.

  In the present embodiment, the case where the stratum structure of the natural ground 13 is composed of the asphalt layer 14, the sandy soil layer 16, and the gravel layer 17 has been studied. Examination according to the site is necessary as appropriate.

Next, the start method and arrival method of the shield machine 1 will be described below.
14 and 15 are a plan view and a side sectional view of the hole 18 for starting and reaching the shield machine 1, respectively.

  As shown in FIGS. 14 and 15, holes 18 for starting and reaching the shield machine 1 to the natural ground 13 are excavated at the starting point and the reaching point, respectively. The hole 18 has a depth 1.3 times the height H of the shield machine 1 and a slope 19 is formed on the entire outer periphery. In addition, in this embodiment, although the case where the slope 19 was formed in the whole outer periphery of the hole 18 was demonstrated, it is not limited to this, The slope 19 is formed only in the advancing direction of the shield machine 1, A retaining wall may be formed on the other side surface.

  First, the starting method of the shield machine 1 will be described, and then the reaching method will be described. In the following description, the holes 18 used for starting and reaching are referred to as a starting hole 18a and a reaching hole 18b, respectively.

FIG. 16 is a side sectional view showing a state in which the gantry 20 and the reaction force wall 21 are installed in the start hole 18a.
As shown in FIG. 16, a gantry 20 along the inclination angle of the tunnel 22 to be excavated and a reaction force wall 21 for obtaining a reaction force when starting the shield machine 1 are constructed on the bottom of the start hole 18a. .

FIG. 17 is a side sectional view showing a state in which the shield machine 1 is installed on the mount 20 in the start hole 18a.
As shown in FIG. 17, the shield machine 1 is installed on the gantry 20. A segment 7 is installed between the rear end of the shield machine 1 and the reaction force wall 21.

18 and 19 are diagrams illustrating a starting method of the shield machine 1.
As shown in FIG. 18, the cutter head 10 of the upper cutter unit 2 and the lower cutter unit 3 is driven to rotate, and the shield jack 5 is extended to propel the shield machine 1 main body. Then, the shield machine 1 enters the ground 13 while excavating the slope 19 located in the traveling direction with the cutter head 10 of the upper cutter unit 2 and the lower cutter unit 3.

The earth covering thickness when the shield machine 1 enters the ground 13 while excavating the slope 19 is 0.3 times the height H of the shield machine 1. Accordingly, since the weight of the earth covering portion is larger than the frictional force generated between the ground pile 13 and the shield machine 1 as the shield machine 1 enters the ground pile 13, the soil in the approach direction of the shield machine 1. The cover is not pulled up and swells.
When the shield machine 1 enters the natural ground 13, a lubricant or the like may be injected between the shield machine 1 and the natural ground 13 to reduce the frictional force between the shield machine 1 and the natural ground 13.
And if the shield machine 1 is dug only a predetermined distance, rotation of the cutter head 10 of the upper cutter part 2 and the lower cutter part 3 is stopped, and excavation is temporarily stopped.

  Next, as shown in FIG. 19, the shield jack 5 is contracted to construct a new segment 7 in the space generated between the tail portion 9 and the segment 7.

  Then, as described above, the cutter heads 10 of the upper cutter unit 2 and the lower cutter unit 3 are driven to rotate and the shield jack 5 is extended to dig a predetermined distance, and then the shield jack 5 is contracted. A series of operations up to the construction of the segment 7 is defined as one cycle, and this cycle is repeated a plurality of times, so that the entire shield machine 1 enters the ground 13 while starting from the start hole 18a.

Next, a method for reaching the shield machine 1 will be described.
FIG. 20 is a side sectional view showing a state in which the gantry 20 is installed in the reaching hole 18b.
As shown in FIG. 20, the gantry 20 is constructed along the inclination angle of the tunnel 22 to be excavated on the bottom of the arrival hole 18 b.

  FIG. 21 is a diagram illustrating a reaching method of the shield machine 1. As shown in FIG. 21, the cutter head 10 of the upper cutter unit 2 and the lower cutter unit 3 is driven to rotate and the shield jack 5 is extended to propel the main body of the shield machine 1 so that it is positioned in the traveling direction. While the slope 19 is excavated by the cutter head 10 of the upper cutter unit 2 and the lower cutter unit 3, the shield machine 1 is caused to enter the reaching hole 18b.

The earth covering thickness when the shield machine 1 enters the reaching hole 18b while excavating the slope 19 is made to enter the reaching hole 18b along the gantry 20, so that the height H of the shield machine 1 is 0. Tripled. Therefore, since the weight of the earth covering portion is larger than the frictional force generated between the ground pile 13 and the shield machine 1 as the shield machine 1 enters the reach hole 18b, the soil machine 1 moves in the traveling direction of the shield machine 1. The cover is not pulled up and swells.
When the shield machine 1 enters the reach hole 18b, a lubricant or the like may be injected between the shield machine 1 and the ground 13 to reduce the frictional force between the shield machine 1 and the ground 13.

FIG. 22 is a side sectional view showing a state in which the shield machine 1 has reached the gantry 20 in the arrival hole 18b.
As shown in FIG. 22, when the upper cutter unit 2 and the lower cutter unit 3 pass the slope 19, the rotation of the cutter heads 10 of both the cutter units 2 and 3 is stopped, and the shield machine 1 is connected to the shield machine 1. It is propelled to the vicinity of the center of the access hole 18b that facilitates the work such as dismantling.

  In the present embodiment, the thickness of the earth covering when entering the natural ground 13 from the start hole 18a and when entering the reaching hole 18b from within the natural ground 13 is 0.3 times the height H of the shield machine 1. Although the case where the depth of the start hole 18a and the arrival hole 18b is 1.3 times the height H of the shield machine 1 has been described so as to be, the present invention is not limited to this value, and the earth covering thickness is shielded. The depth of the start hole 18a and the arrival hole 18b may be increased so as to be larger than 0.3 times the height H of the machine 1. However, when the depths of the start hole 18a and the arrival hole 18b are deeper than 1.7 times the height H of the shield machine 1, the start hole 18a and the arrival hole 18b are greatly excavated, and a general shaft is constructed. Since the same construction period and cost as in the case are required, the depth of the start hole 18a and the arrival hole 18b is preferably 1.7 times or less the height H of the shield machine 1. That is, it is preferable that the cover thickness is 0.7 times or less.

  According to the shield machine 1 in the present embodiment described above, the upper cutter unit 2 is disposed so as to protrude in the traveling direction from the lower cutter unit 3, and the upper cutter unit 2 is always the lower cutter unit 3. Since the natural ground 13 is excavated prior to the excavation, the excavation target cross section can be divided into small portions for excavation. In addition, since the remaining section is excavated by the lower cutter portion 3 while the upper cutter portion 2 supports the earth covering portion, the influence on the earth covering portion due to excavation can be eliminated. Therefore, compared to full-section excavation, even when excavating a ground with a small covering, there is no possibility that ground deformation will occur. As a result, it is not necessary to carry out countermeasure work for ground deformation such as ground improvement on the portion of the small covering, so that the construction period can be shortened and the construction cost can be reduced.

  Moreover, since the upper cutter unit 2 and the lower cutter unit 3 have only a simple device such as a driving device for rotating the cutter, the weight of the front portion of the shield machine 1 is advanced in the traveling direction independently. Or it can reduce compared with the conventional shield machine provided with the mechanism which moves backward. Therefore, linear control during propulsion is facilitated, and the tunnel 22 can be excavated accurately. Further, since the number of devices in the main body of the shield machine 1 can be reduced, the capital investment cost of the main body of the shield machine 1 can be reduced.

  Furthermore, since each cutter part 2 and 3 is provided with the some cutter head 10, respectively, the combination of these cutter heads 10 can respond | correspond to the tunnel 22 of various excavation cross-sectional shapes and magnitude | sizes.

  Moreover, since the shield machine 1 starts from the start hole 18a in which the slope 19 by the natural ground 13 is formed in the traveling direction, and enters the natural ground 13 while excavating the slope 19, It is possible to enter the natural ground 13 in a shorter time than when excavating a retaining wall constructed of concrete or the like. Then, when reaching the arrival hole 18b, as in the case of the start, since it enters the arrival hole 18b while excavating the slope 19 composed of the natural ground 13, it enters in a shorter time than when excavating the retaining wall. can do.

  Further, when the shield machine 1 enters the natural ground 13 from the start hole 18a and when entering the reach hole 18b from the natural ground 13, the thickness of the earth covering is 0.3 times the height H of the shield machine 1 or more. Therefore, the weight of the earth covering portion becomes larger than the friction force generated between the ground 13 and the shield machine 1. Therefore, the earth covering portion is not pulled up in the traveling direction of the shield machine 1.

  Further, by assembling or disassembling the shield machine 1 in the start hole 18a and the reach hole 18b, the side surfaces of the start hole 18a and the reach hole 18b are replaced by soundproof walls, and this occurs when the shield machine 1 is assembled or disassembled. Noise can be reduced. Therefore, the influence on the surrounding living environment can be reduced.

  In the present embodiment, the case where the shield machine 1 is started or reached in an inclined state has been described. However, the present invention is not limited to this, and the shield machine 1 may be started or reached horizontally. However, when the shield machine 1 excavates the slope 19 and enters the natural ground 13 or enters the access hole 18b, the covering portion is at least 0.3 times the height H of the shield machine 1 Therefore, the earth covering portion is not pulled in the traveling direction of the shield machine 1.

It is a front view of the shield machine concerning the embodiment of the present invention. It is a sectional side view of the shield machine concerning the embodiment of the present invention. It is a figure which shows the analysis model for two-dimensional of the natural ground of excavation object. It is a figure which shows the excavation method of the natural ground in an analysis case (a). It is a figure which shows the excavation method of the natural ground in an analysis case (b). It is a figure which shows the excavation method of the natural ground in an analysis case (c). It is a figure which shows the analysis result of the subsidence amount by the whole cross-section excavation of the analysis case (a). It is a figure which shows the analysis result of the amount of subsidence by up-and-down level excavation which makes the preceding amount of the upper cutter part of an analysis case (b) 1.0m. It is a figure which shows the analysis model for three-dimensional of a natural ground. It is a figure which shows the excavation method of the natural ground in an analysis case (d). It is a figure which shows the excavation method of the natural ground in an analysis case (e). It is sectional drawing which showed the analysis result of the sinking amount by the whole cross-section excavation of the analysis case (d), and expanded the one side of the excavation cross section. It is sectional drawing which showed the analysis result of the amount of subsidence by up-and-down level excavation of an analysis case (e), and expanded the one side of the excavation cross section. It is a top view of the hole for making a shield machine start and reach | attain. It is a sectional side view of the hole for starting and reaching a shield machine. It is a sectional side view which shows the state which installed the mount frame and reaction force wall in the starting hole. It is a sectional side view which shows the state which installed the shield machine on the mount frame in a starting hole. It is a figure which shows the start method of a shield machine. It is a figure which shows the start method of a shield machine. It is a sectional side view which shows the state which installed the mount frame in the arrival hole. It is a figure which shows the arrival method of a shield machine. It is a sectional side view which shows the state which the shield machine reached | attained on the mount frame in an arrival hole.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Shield machine 2 Upper cutter part 3 Lower cutter part 4 Hood part 5 Shield jack 6 Girder part 7 Segment 8 Electa 9 Tail part 10 Cutter head 11 Drive source 12 Screw conveyor 13 Ground mountain 14 Asphalt layer 16 Sandy soil layer 17 Gravel layer 18a Starting hole 18b Reaching hole 19 Slope 20 Mounting base 21 Reaction wall 22 Tunnel A Analytical model shield machine B Analytical model shield machine C Analytical model shield machine D Analytical model shield machine H Height of shield machine

Claims (6)

A shield machine for digging in the ground,
Cutter parts that can be driven independently from each other are arranged in the upper and lower stages at the front part of the shield machine, and these upper and lower cutter parts are such that the upper cutter part protrudes in the advancing direction from the lower cutter part. Shield machine characterized by being fixedly arranged in   The shield machine according to claim 1, wherein each of the upper cutter unit and the lower cutter unit includes a plurality of cutters. Cutter parts that can be driven independently from each other are arranged in the upper and lower stages at the front part of the shield machine, and these upper and lower cutter parts are such that the upper cutter part protrudes in the advancing direction from the lower cutter part. Install the shield machine fixedly arranged in the hole where the slope is formed in the traveling direction,
A starting method for a shielding machine, characterized in that the shielding machine is propelled toward the slope, and the slope is excavated to enter a natural mountain.   The shield machine according to claim 3, wherein a covering thickness when the shield machine excavates the slope and enters a natural ground is 0.3 times or more the height of the shield machine. How to start.   Cutter parts that can be driven independently from each other are arranged in the upper and lower stages at the front part of the shield machine, and these upper and lower cutter parts are such that the upper cutter part protrudes in the advancing direction from the lower cutter part. When the shield machine fixedly arranged on the ground reaches the hole where the slope is formed from within the natural ground, the shield machine is propelled toward the slope, and the slope is excavated into the hole. A method of reaching a shield machine, characterized in that it is reached.   The shield machine according to claim 5, wherein a covering thickness when the shield machine reaches the hole by excavating the slope is 0.3 times or more the height of the shield machine. How to reach.