JP6355148B1 - Box culvert insertion aid - Google Patents

Abstract

In a conventional construction method, when a concrete box is installed in a narrow excavation hole, the side wall of the concrete box collides with the side wall of the excavation hole, the side wall of the excavation hole collapses, and a house is formed around the excavation hole. In some cases, there was a problem that the surrounding houses tilted. In the present invention, the side elastic body is provided on the side surface of the box culvert. Therefore, even if the side surface of the box culvert collides with the side wall of the excavation hole, The collision force is alleviated, the side wall of the excavation hole is not collapsed, and even when there are houses around the excavation hole, it is possible to prevent the surrounding houses from being inclined. [Selection] Figure 1

Description

  The present invention relates to a box culvert insertion assisting instrument used when a box culvert is installed in a drilled excavation hole using a Messel shield device.

  Conventionally, a box culvert installation method is known in which a box culvert is installed in a drilled hole using a Messel shield device or the like. As this box culvert installation method, an open shield method is known.

  This open shield construction method is a construction method in which a box laying is performed while propelling using an upper open type shield machine to prevent sediment collapse, and is performed using the open shield machine 101 (FIGS. 14 and 15). reference). Here, FIG. 14 is an explanatory diagram when the box is installed in the conventional open shield method, and FIG. 15 is an explanatory diagram when the box is connected in the open shield method.

  The open shield machine 101 divides the machine body in the front-rear direction, the front end of the tail part 101b of the rear machine body is fitted into the rear end of the front part 101a of the front machine body, and the middle folded part 102 is formed by the mutual fitting part. And bendable.

  The front portion 101a mainly performs excavation, and has a front end and an upper surface as open surfaces, and the middle jacks are arranged in the upper and lower sides in a rearward direction toward the rear and rearwardly in a plurality of stages.

  The tail portion 101b is used to install the concrete box 104. The tail portion 101b has a bottom plate 105, and a propulsion jack (shield jack) 103 is arranged on the left and right sides of the body toward the front and rearward, and in a plurality of stages. Arranged.

  The open shield machine 101 is installed in the start shaft, and the propulsion jack 103 is extended to take the reaction force against the reaction force wall in the start shaft to advance the open shield machine 101, and the concrete box 104 is moved from above by the crane 114. The suspension is suspended and set behind the propulsion jack 103 contracted in the tail portion 101b of the open shield machine 101. Then, the excavator 107 is used to excavate earth and sand from the front or upper surface of the open shield machine 101, and the earth and sand are discharged. Then, at the same time as the earth removal or after that, the propulsion jack 103 is extended to advance the open shield machine 101.

 When the concrete box 104 is suspended in the tail portion 101b of the open shield machine 101, a height adjusting material such as a concrete block is disposed under the concrete box 104, and the tail box 101b Primary injection is performed by filling the voids on the left and right sides and the lower part of the concrete box 104 with a back-filling injection material 109 using an instantaneous setting grout material. Further, after advancement of the open shield machine 101, back injection material 109 is injected into the outside by a grout hole from the inside of the concrete box 104 as secondary injection (for example, Patent Document 1). .

JP-A-2018-12984 (prior art)

  In the conventional open shield method, the concrete box 104 is installed in the excavated excavation hole using the open shield machine 101, and the concrete box 104 installed on the wall surface of the excavated excavation hole and the excavation hole. Since the concrete box 104 installed in the excavation hole collides with the side wall of the excavation hole and the side wall does not collapse, the excavation hole is formed on a narrow road or the like. In the case of excavation, the width of the excavation hole is inevitably narrowed, and if the concrete box 104 is installed in such a narrow excavation hole, the side surface of the concrete box 104 also collides with the side wall of the excavation hole. As described above, when the side surface of the concrete box 104 collides with the side wall of the excavation hole, the side wall of the excavation hole collapses due to the collision force between the side surface of the concrete box 104 and the side wall of the excavation hole, and a house is formed around the excavation hole. In some cases, there is a problem that the surrounding houses are inclined, and the colliding concrete box is also damaged, causing a problem that water leaks from the damaged place.

  In addition, when the concrete box 104 is suspended from above by a crane 114 in a narrow excavation hole, the concrete box 104 is installed when the concrete box 104 swings left and right when the concrete box 104 is inserted into the narrow excavation hole. There was a problem that it became difficult.

  The present invention has been made in view of the above problems. Even when the box culvert collides with the side wall of the excavation hole, the surrounding house does not tilt, and the box culvert swings to the left and right when the box culvert is inserted. However, it is intended to provide a box culvert insertion auxiliary device that does not hinder the installation work of underground buried structures and can eliminate water leakage from the box culvert due to damage to the box culvert. It is.

  In order to solve the above-described problems and achieve the above-described object, the first aspect of the present invention is a box culvert insertion used when a box culvert is installed in a drilled excavation hole using a Messel shield device. At least two auxiliary tools are provided substantially parallel to the left and right side surfaces of the upper surface of the box culvert, and at least two bolt holes are formed on a surface parallel to the upper surface of the box culvert formed in a substantially rectangular shape. The box culvert fixing plate and the mounting bolt inserted into the bolt hole of the box culvert fixing plate and connected to the box culvert, and the mounting bolt inserted into the bolt hole of the box culvert fixing plate are attached to the box. Suspension chain for suspending culvert and end of box culvert fixing plate in the same direction The upper support plate which is provided with two members joined together and extends linearly to the substantially side surface of the box culvert in the direction orthogonal to the box culvert fixing plate, and the end portions of the upper surface support plate in the same direction are the side surfaces of the box culvert. A side support plate provided by being coupled to each other along the side, and a side elastic body formed of an elastic body and attached to the side support plate in the lateral direction of the side surface of the box culvert. The box culvert suspended by the crane via the suspension chain can reduce the impact when the side surface collides with the ground.

  According to the present invention, the side surface of the box culvert is provided with the side surface elastic body that is formed of the elastic body and is attached to the side surface support plate in the lateral direction of the side surface of the box culvert. Even if it collides with the side wall of the hole, the impact force of the side wall of the excavation hole is reduced by the side elastic body, the side wall of the excavation hole does not collapse, and even if there are houses around the excavation hole, the surrounding houses tilt Can be prevented. Further, since the box culvert is not damaged by the side elastic body, water leakage from the box culvert due to the damage of the box culvert can be eliminated. Further, even when the box culvert is swung from side to side and inserted into a narrow excavation hole, the side elastic body provided on the side surface of the box culvert collides with the side wall of the excavation hole, thereby Since the elastic body serves as a cushion and the box culvert is directed toward the center, it is easy to insert the box culvert straight into the excavation hole.

  The second aspect of the present invention is the box culvert insertion assisting instrument according to the first aspect, wherein the box culvert fixing plates are all substantially the same shape, and the bolt holes are formed at the same place. It is characterized by that.

  According to the present invention, all the box culvert fixing plates have substantially the same shape, and the bolt holes are formed at the same place, so that the box culvert can be suspended by the crane via the suspension chain with good balance. .

  According to a third aspect of the present invention, there is provided a box culvert insertion assisting instrument according to the first aspect, wherein the side surface support plate has end portions in the same direction of the upper surface support plate along the side surface of the box culvert. It is a square frame shape that extends linearly from substantially both ends that are linearly connected to the lower side of the box culvert and has both ends at the lower end connected above the lower side of the box culvert. It is attached to at least the upper part and the lower part of the side support plate substantially in parallel.

  According to the present invention, the side elastic body is attached at least to the upper and lower portions of the side support plate substantially parallel to the lower side of the box culvert. Therefore, even when the side surface of the box culvert collides with the side wall of the excavation hole, Therefore, the collision force with the side wall of the excavation hole can be reliably collided, and the collision force with the side wall of the excavation hole can be reliably reduced.

  According to a fourth aspect of the present invention, there is provided a box culvert insertion assisting instrument according to the first aspect, wherein the side surface support plate is formed so that the end portions in the same direction of the upper surface support plate are aligned with the side surface of the box culvert. It is a square frame shape that extends linearly from the substantially opposite ends of the box culvert to the lower side of the box culvert and has the lower end ends joined at the upper side of the lower side of the box culvert. It is attached over substantially the entire circumference of the side support plate.

  According to the present invention, since the side elastic body is attached over substantially the entire circumference of the square frame-shaped side support plate, even when the side surface of the box culvert collides with the side wall of the excavation hole, the side elastic body is excavated from the side elastic body. It can be made to collide reliably by the side wall of a hole, and the collision force with the side wall of a digging hole can be relieved more reliably.

  According to a fifth aspect of the present invention, there is provided a box culvert insertion assisting device according to the first aspect, wherein the side elastic body has a hollow inner surface and an outer surface substantially secondary from the bottom surface toward the outer side. It is characterized by being formed in a curved shape.

  According to the present invention, the side elastic body has a hollow inner surface and an outer surface formed in a substantially quadratic curve shape from the bottom surface to the outer side, so that the top of the side elastic body collides with the side wall of the excavation hole. Later, when the side elastic body is deformed inward, the collision force with the side wall of the excavation hole is alleviated, and the box culvert can be protected from being damaged.

  According to the present invention, even if the box culvert collides with the side wall of the excavation hole, the surrounding houses are not tilted, and water leakage from the box culvert due to breakage of the box culvert can be eliminated. Furthermore, even when the box culvert is swung from side to side when the box culvert is inserted, it is possible to prevent the installation work of the underground structure from being hindered.

It is a figure which shows the state which attached the box culvert insertion auxiliary instrument in one Embodiment of this invention to the box culvert. It is a top view which shows the state which attached the box culvert insertion auxiliary tool to the box culvert. (A) It is a side view which shows the state which attached the box culvert insertion auxiliary tool to the box culvert. (B) It is AA sectional drawing of Fig.3 (a). It is a top perspective view of the box culvert insertion auxiliary instrument. It is a disassembled perspective view of the box culvert insertion auxiliary instrument. (A) It is a top perspective view of the side elastic body of the box culvert insertion auxiliary instrument. (B) It is a figure which shows the method of installing the side elastic body of the box culvert insertion auxiliary tool in a side surface support plate. It is a figure which shows having installed the side elastic body of the box culvert insertion auxiliary instrument only in the upper part of a side surface support plate. It is a figure which shows having installed the side elastic body of the box culvert insertion auxiliary tool in the perimeter of the square frame shape of a side surface support plate. It is a figure which shows the construction condition of the Messel shield apparatus in which the same box culvert insertion auxiliary instrument is used. It is a perspective view of the same Messel shield device. It is an internal structure figure of the same Messel shield device. It is a flowchart of the open pit construction method in which the box culvert insertion auxiliary instrument in one embodiment of the present invention is used. It is a figure which shows the construction condition of the open pit construction method. It is explanatory drawing at the time of the box installation of the conventional open shield method. It is explanatory drawing at the time of the box connection of the open shield construction method.

  A box culvert insertion assisting device according to an embodiment of the present invention will be described with reference to the drawings. Here, FIG. 1 is a view showing a state in which the box culvert insertion assisting device is attached to the box culvert in one embodiment of the present invention, and FIG. 2 is a top view showing a state in which the box culvert insertion assisting device is attached to the box culvert. FIG. 3A is a side view showing a state in which the box culvert insertion assisting device is attached to the box culvert, and FIG. 3B is a cross-sectional view taken along line AA of FIG.

  The box culvert 1 is a structure that is buried under the road and used for sewers and drainage pipes. When the box culvert 1 is buried in the ground, the ground is excavated as described later. Then, the bottom of the excavated ground is solidified, and the box culvert 1 is suspended on the solidified ground by a crane 2 described later and inserted into the excavation hole. The box culvert insertion assisting instrument 3 is used when a box culvert is installed by using the Messel shield device 15 described later in the excavated hole.

  Next, the box culvert insertion assisting device will be specifically described with reference to FIGS. Here, FIG. 4 is a top perspective view of the box culvert insertion assisting instrument in one embodiment of the present invention, and FIG. 5 is an exploded perspective view of the box culvert insertion assisting instrument.

  The box culvert insertion assisting device 3 includes a box culvert fixing plate 4, a mounting bolt 5, a suspension chain 6, an upper surface support plate 7, a side surface support plate 8, and a side surface elastic body 10.

  The box culvert fixing plate 4 is made of steel (SS400), and has an L-shaped angle with an L-shaped cross section and a substantially rectangular bottom surface. Two box culvert fixing plates 4 are provided substantially parallel to the left and right side surfaces of the upper surface of the box culvert 1, and bolt holes 11 are formed on the surfaces parallel to the upper surface of the box culvert 1 formed in a substantially rectangular shape. Individually formed. In the present embodiment, two box culvert fixing plates 4 having the same shape are provided. However, the present invention is not limited thereto, and a plurality of box culvert fixing plates 4 having the same shape, such as three or four, that is, at least two are provided. It may be. Further, in the present embodiment, 11 bolt holes 11 are formed on the lower surface of the box culvert fixing plate 4. However, the present invention is not limited to this, and 3 to 11 pieces (preferably 5 to 11 pieces are preferably provided) in the same place. (More preferably, 7 to 11 pieces), that is, at least two pieces may be provided.

  The mounting bolt 5 is inserted into the bolt hole 11 of the box culvert fixing plate 4 to couple the box culvert fixing plate 4 to the box culvert 1. Specifically, an anchor bolt is used as the mounting bolt 5, and the bolt is inserted into a mounting bolt insertion hole (not shown) of the box culvert 1 through the bolt hole 11 of the box culvert fixing plate 4. Here, a mounting bolt insertion hole (not shown) is formed in advance at a position where the bolt hole 11 of the box culvert fixing plate 4 on the upper side of the box culvert 1 is located. This mounting bolt insertion hole (not shown) may be formed in all locations where the bolt hole 11 of the box culvert fixing plate 4 on the upper side of the box culvert 1 is located, but if the bolt hole 11 to be used is determined in advance, A mounting bolt insertion hole (not shown) may be formed only at a location corresponding to the bolt hole 11. In addition, a mounting bolt chain mounting portion 12 for mounting the suspension chain 6 is provided on the top of the mounting bolt 5.

  The suspension chain 6 is attached to the mounting bolt 5 inserted into the bolt hole 11 and suspends the box culvert 1. Specifically, a suspension chain bolt mounting portion 13 is provided at the lower end of the suspension chain 6, and the suspension chain bolt mounting portion 13 of the suspension chain 6 is connected to the mounting bolt chain mounting portion 12 of the mounting bolt 5. By being inserted, the suspension chain 6 and the mounting bolt 5 can be coupled. The suspension chain 6 is a chain with a chain length adjusting bracket, and the length of each chain can be adjusted at the upper part of the suspension chain 6. A suspension chain hook engaging portion 9 is provided on the upper portion of the suspension chain 6, and the hook 14 of the crane 2 is engaged with the suspension chain hook engaging portion 9 to suspend the box culvert 1. be able to.

  The upper surface support plate 7 is provided with two end portions in the same direction of the box culvert fixing plate 4 coupled to each other, and is near (substantially the side surface) reaching the side surface of the box culvert 1 in a direction perpendicular to the box culvert fixing plate 7. It is formed so as to extend linearly. That is, since the two box culvert fixing plates 4 are attached substantially parallel to the left and right side surfaces of the upper surface of the box culvert 1, "the ends of the box culvert fixing plate 4 in the same direction" The front end portions and rear end portions of the culvert fixing plate 4 are connected to each other by connecting the front end portions and rear end portions of the box culvert fixing plate 4 separately in the direction orthogonal to the box culvert fixing plate 7. The book is provided. Specifically, the upper surface support plate 7 is an L-shaped angle with an L-shaped cross section, and the outer side surface and the end portion of the box culvert fixing plate 4 are joined by welding. In the present embodiment, the upper surface support plate 7 is formed so as to extend to the front of the side surface of the box culvert 1. However, the present invention is not limited to this, and the upper surface and the side surface of the box culvert 1 are not limited to this. You may form so that it may extend to the place beyond the corner | angular part.

  The side surface support plate 8 is provided by joining the end portions in the same direction of the upper surface support plate 7 along the side surface of the box culvert 1. That is, since the upper surface support plate 7 extends linearly in the direction orthogonal to the box culvert fixing plate 7 to the front of the side surface of the box culvert 1, “the ends of the upper surface support plate 7 in the same direction” Is the front end portions and the rear end portions of the upper surface support plate 7, and is provided by connecting the front end portions and the rear end portions of the upper surface support plate 7 along the side surfaces of the box culvert 1. Yes. Specifically, the side support plate 8 is an L-shaped angle 8a (8) having an inverted L-shaped cross section, and the inner surface of the L-shaped angle 8a (8) and the end portion of the upper surface support plate 7 are joined by welding. Has been. Further, the side support plate 8 is a flat bar 8 b (8) having an I-shaped cross section, and is formed from the end of the upper support plate 7 to the lower side of the box culvert 1. Specifically, the side surface support plate 8 has a side surface of the box culvert 1 extending from both ends of the L-shaped angle 8 a (8) in which the end portions of the upper surface support plate 7 are linearly coupled along the side surface of the box culvert 1. A flat bar 8b (8) is formed linearly downward, and a square in which the lower end ends of the flat bar 8b (8) are joined by a flat bar 8c (8) above the lower side of the box culvert 1 It has a frame shape (hollow square shape). That is, the side support plate 8 is formed by joining the lower surface of the side of the L-shaped angle 8a (8) to the upper ends of the left and right flat bars 8b (8) and the lower ends of the left and right flat bars 8b (8). And the upper side surface of the lower flat bar 8c (8) are joined together by welding. In this way, the side support plate 8 linearly connects the end portions of the upper surface support plate 7 in the same direction along the side surface of the box culvert 1 with the L-shaped angle 8a (8), and further the flat bar 8b (8 ) Extending along the lower side of the side of the box culvert 1, and a flat frame 8 c (8) is formed in a square frame shape (hollow square shape) in which both lower end ends are coupled to the upper side of the lower side of the box culvert 1. . In the present embodiment, the rectangular frame shape (hollow rectangular shape) is used. However, the shape is not limited to this, and the end portions in the same direction of the upper surface support plate 7 are joined together along the side surface of the box culvert 1. If it is, for example, it may be formed in a U-shape excluding the flat bar 8c (8) at the bottom of the square frame shape (hollow square shape). Thus, the side elastic body 10 can be attached to the lower side of the side support plate 8 by forming the side support plate 8 in a U-shape. In the present embodiment, the side support plate 8 is formed by the L-shaped angle 8a (8), the flat bar 8b (8), and the flat bar 8c (8). You may make it.

  The side elastic body 10 is formed of an elastic body made of a thermoplastic elastomer (a plate portion: polypropylene), and is attached to the side support plate 8 in the lateral direction of the box culvert 1. That is, two side elastic bodies 10 are attached to the upper and lower portions of the side support plate 8 in parallel with the lower side of the box culvert 1. The side elastic body 10 has an inner surface having a hollow shape and an outer surface formed in a quadratic curve shape from the bottom surface to the outside (see FIG. 6A). As described above, the side elastic body 10 has a hollow inner surface and an outer surface formed in a quadratic curve shape from the bottom surface to the outer side. Therefore, after the top of the side elastic body 10 collides with the side wall of the excavation hole. When the side elastic body 10 is deformed inward, the collision force with the side wall of the excavation hole is alleviated, and the box culvert 1 can be protected from being damaged. In the side elastic body 10, the side elastic body coupling screw 37 is inserted into the screw insertion hole 38 in the head of the side elastic body 10, and the side elastic body coupling screw 37 inserted into the screw insertion hole 38 is the side support plate 8. The side elastic body 10 is installed on the side support plate 8 by screwing with the side support plate screw insertion hole 39 (see FIG. 6B). Here, a thread is formed in advance in the side support plate screw insertion hole 39 of the side support plate 8. Here, FIG. 6A is a top perspective view of the side elastic body of the box culvert insertion assisting device in one embodiment of the present invention, and FIG. 6B is a side view of the side elastic body of the box culvert insertion assisting device. It is a figure which shows the method of installing in a support plate. In the present embodiment, the thermoplastic elastomer (the plate part: polypropylene) is used as a material. However, the present invention is not limited to this, and the material may be formed from a material having another elastic force. In the present embodiment, the side elastic bodies 10 are attached to the upper and lower portions of the side support plate 8 in parallel to the lower side of the box culvert 1, but this is not limiting, and the side support plate 8 is substantially parallel to the lower side of the box culvert 1. It may be attached only to the upper part (see FIG. 7), or may be attached over substantially the entire circumference of the side support plate 8 in the shape of a square frame (see FIG. 8). In the present embodiment, the side elastic body 10 is formed with a quadric curve shape with the outer surface extending from the bottom surface to the outside. However, the present invention is not limited thereto, and the outer surface is formed with a substantially quadratic curve shape from the bottom surface to the outside. Other shapes may be used. Here, FIG. 7 is a view showing that the side elastic body of the box culvert insertion assisting device in one embodiment of the present invention is installed only on the upper part of the side support plate, and FIG. 8 is a side view of the box culvert insertion assisting device. It is a figure which shows having installed the elastic body in the perimeter of the square frame shape of a side surface support plate.

  Next, the construction status of the Messel shield device 15 in which the box culvert insertion assisting tool 3 is used will be described with reference to the drawings. Here, FIG. 9 is a figure which shows the construction condition of the Messel shield apparatus in which the box culvert insertion auxiliary instrument in one Embodiment of this invention is used.

  As shown in FIG. 9, the box culvert 1 is laid using a messel shield device 15 having a self-propelled function and buried in the ground. Here, in the open pit construction method, the ground is excavated, the bottom of the excavated ground is solidified, and the ground shield such as the box culvert 1 is used on the solidified ground by using the Messel shield device 15 having a self-propelled function. This is a method of laying an embedded structure, and after the box culvert 1 is laid, it is returned to its original state even when the excavated ground is buried.

  Next, the message shield device 15 in which the box culvert insertion aid 3 is used will be described with reference to FIGS. 10 and 11. Here, FIG. 10 is a perspective view of the Messel shield device in which the box culvert insertion assisting device according to the embodiment of the present invention is used, and FIG. 11 is an internal structure diagram of the Messel shield device.

  The Messel shield device 15 includes a rigid front frame 16 and a tail frame 17, and an intermediate jack 18 is coupled between the front frame 16 and the tail frame 17. In the front frame 16, a cut beam 21 is disposed between left and right frames integrally formed of a vertical column member 19 and a horizontal reinforcing member 20. Further, the horizontal beam 22 extending in front of the tail frame 17 is placed on a support beam 23 extending in the rear of the front frame 16 so as to prevent the tail frame 17 from sinking. . A front message 24 and a tail message 25 are slidably arranged on both sides of the front frame 16 and the tail frame 17, and the front message 24 and the tail message 25 are connected by pins. The front frame 16 and each front message 24 are connected by press-fit jacks 26. Further, a bottom messel 28 is slidably disposed on the bottom of the front frame 16 via a bottom jack 27. Further, a sled body 29 is disposed at the bottom of the tail frame 17. Then, by operating the press-fit jack 26, the front message 24 is dug in the cutting direction, and by operating the bottom jack 27, the bottom message 28 is dug in the cutting direction, and the contraction of the intermediate jack 18 causes the tail frame 17 to move. It is drawn toward the front frame 16. Control of the press-fit jack 26, the bottom jack 27, and the intermediate jack 18 is performed by a control unit 30 mounted on the upper portion of the front frame 16.

  In the tail frame 17, the tail messels 25 are supported by a frame 33 integrally formed of a vertical column member 31 and a lateral reinforcing member 32, and a plane U-shaped cut beam 34 is disposed in front of the frame 33 with a lateral reinforcing member 32. And a reinforcing material (not shown) is provided at the joint between the cut beam 34 and the lateral reinforcing material 32. A suspending space 36 for suspending the box culvert 1 is formed between the opposing frame bodies 33. The hanging space 36 is open above and behind the space.

  Next, the construction procedure of the open pit construction method in which the box culvert insertion assisting device in one embodiment of the present invention is used will be described with reference to FIGS. FIG. 12 is a flowchart of an open pit construction method in which the box culvert insertion assisting device according to one embodiment of the present invention is used, and FIG. 13 is a diagram showing a construction status of the open pit construction method.

  First, in S1, an excavation process is performed. In this excavation process, an excavation hole for embedding the box carbonate 1 is excavated by using the back for 35 (see FIG. 13A). In this embodiment, the box carbonate 1 (width 1780 mm, height 1820 mm, depth 2000 mm) is buried in a place where the width of the excavation hole cannot be widened (width 2180 mm) because the road width is narrow. Then, the process proceeds to S2.

  In S2, the Messel shield machine forward step is performed. In this Messel shield machine advance step, the Messel shield device 15 is advanced. Specifically, the Messel shield device 15 is advanced by the length of the box culvert 1 in the longitudinal direction. This Messel shield device 15 penetrates the left and right front messels 24 one by one into the natural ground → penetrates the bottom messels 28 one by one into the natural ground → compresses the press-fit jack 26 and the bottom jack 27 (advance the front frame 16) → The intermediate jack 18 is advanced by retracting (promoting the tail frame 17) (see FIG. 11). Then, the process proceeds to S3.

  In S3, a box culvert installation step is performed. In this box culvert installation step, the hook 14 of the crane 2 is engaged with the suspension chain hook engaging portion 9 on the upper part of the suspension chain 6 of the box culvert insertion assisting device 3 attached to the box culvert 1, and the box culvert 1 is attached. It is installed behind the Messel shield machine 15 while being suspended. In this embodiment, since the side elastic body 10 is provided on the side surface of the box culvert 1, even if the side surface of the box culvert 1 collides with the side wall of the excavation hole, the side elastic body 10 causes the collision force of the side wall of the excavation hole. Is relaxed, the side wall of the excavation hole does not collapse, and even if there are houses around the excavation hole, it is possible to prevent the surrounding houses from tilting. Further, since the box culvert 1 is not damaged by the side elastic body 10, it is possible to eliminate water leakage from the box culvert 1 due to the damage of the box culvert 1. Further, even when the box culvert 1 is swung from side to side and inserted into a narrow excavation hole, the side elastic body 10 provided on the side surface of the box culvert 1 collides with the side wall of the excavation hole. Since the side elastic body 10 on one side serves as a cushion and the box culvert 1 is directed toward the center, it is easy to insert the box culvert 1 straight into the excavation hole. Then, the process proceeds to S4.

  In S4, a box culvert insertion assisting device removing step is performed. In the box culvert insertion assisting instrument removing step, the box culvert insertion assisting instrument 3 is removed from the box culvert 1. Specifically, the box culvert insertion assisting device 3 is removed from the box culvert 1 by removing the mounting bolt 5 from the mounting bolt insertion hole (not shown) of the box culvert 1 through the bolt hole 11 of the box culvert fixing plate 4. Can do. Then, the process proceeds to S5.

  In S5, it is determined whether to install the next box culvert 1. If “YES” is determined in S5, the process proceeds to S1, and the processes of S1, S2, S3, and S4 are repeatedly performed until “NO” is determined in S5. If "NO" is determined in S5, the open pit method is completed.

  As described above, in the present embodiment, since the side elastic body 10 is provided on the side surface of the box culvert 1, even if the side surface of the box culvert 1 collides with the side wall of the excavation hole, The side wall of the excavation hole is not collapsed, and even if there are houses around the excavation hole, the surrounding houses can be prevented from tilting. Further, since the box culvert 1 is not damaged by the side elastic body 10, it is possible to eliminate water leakage from the box culvert 1 due to the damage of the box culvert 1. Further, even when the box culvert 1 is swung from side to side and inserted into a narrow excavation hole, the side elastic body 10 provided on the side surface of the box culvert 1 collides with the side wall of the excavation hole. Since the side elastic body 10 on one side serves as a cushion and the box culvert 1 is directed toward the center, it is easy to insert the box culvert 1 straight into the excavation hole.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 Box culvert 2 Crane 3 Box culvert insertion auxiliary tool 4 Box culvert fixing plate 5 Mounting bolt 6 Suspension chain 7 Upper surface support plate 8 Side surface support plate 9 Suspension chain hook locking part 10 Side elastic body 11 Bolt hole 12 Mounting bolt chain Mounting portion 13 Suspension chain bolt mounting portion 14 Hook 15 Messel shield device 16 Front frame 17 Tail frame 18 Intermediate jack 19 Vertical column member 20 Horizontal reinforcing material 21 Cut beam 22 Horizontal beam 23 Support beam 24 Front message 25 Tail message 26 Press-fit jack 27 Bottom Jack 28 Bottom Messel 29 Sled Body 30 Control Unit 31 Vertical Column Material 32 Horizontal Reinforcement Material 33 Frame Body 34 Cut Beam 35 Back For 36 Lifting Space 37 Side Elastic Body Coupling Screw 38 Screw Insertion Hole 39 Side Support Screw insertion hole

Claims (5)

A box culvert insertion aid used when installing a box culvert in a drilled excavation hole using a Messel shield device,
A box culvert fixing plate provided with at least two bolt holes in a plane parallel to the upper surface of the box culvert formed in a substantially rectangular shape, provided at least two in parallel with the left and right side surfaces of the box culvert upper surface; ,
A mounting bolt that is inserted into the bolt hole of the box culvert fixing plate and connects the box culvert fixing plate to the box culvert;
A suspension chain that is attached to the mounting bolt inserted into the bolt hole of the box culvert fixing plate and suspends the box culvert;
Two end portions in the same direction of the box culvert fixing plate are coupled to each other, and an upper surface support plate that extends linearly to a substantially side surface of the box culvert in a direction orthogonal to the box culvert fixing plate,
Side support plates provided in such a manner that the end portions in the same direction of the upper support plates are respectively coupled along the side surfaces of the box culverts;
A side elastic body formed from an elastic body and attached to the side support plate in the lateral direction of the side surface of the box culvert;
The box culvert insertion assisting device, wherein the side elastic body alleviates an impact when a side surface of the box culvert suspended by the crane through the suspension chain collides with the ground.   2. The box culvert insertion assisting device according to claim 1, wherein each of the box culvert fixing plates has substantially the same shape and the bolt holes are formed at the same place. The side support plate linearly extends from substantially both ends of the upper surface support plate in the same direction along the side surface of the box culvert to the lower side of the box culvert, and has both ends at the lower end. It is a square frame shape joined at the upper part from the lower side of the box culvert,
2. The box culvert insertion assisting device according to claim 1, wherein the side elastic body is attached at least to an upper part and a lower part of the side support plate substantially parallel to a lower side of the box culvert. The side support plate linearly extends from substantially both ends of the upper surface support plate in the same direction along the side surface of the box culvert to the lower side of the box culvert, and has both ends at the lower end. It is a square frame shape joined at the upper part from the lower side of the box culvert,
2. The box culvert insertion assisting device according to claim 1, wherein the side elastic body is attached over substantially the entire circumference of the side support plate having a square frame shape. 2. The box culvert insertion assisting device according to claim 1, wherein the side elastic body has an inner surface formed in a hollow shape and an outer surface formed in a substantially quadratic curve shape from the bottom surface toward the outside.

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