JP4789674B2 - Civil engineering construction method - Google Patents

Description

The present invention relates to a method of constructing civil engineering construction.

In the construction method of the civil engineering structure, as shown in Patent Document 1, concrete plates are sequentially arranged from the lower side to the upper side along the slope with a certain interval from the slope, and It has been proposed that concrete be poured from the upper side between each concrete plate and the slope. Specifically, the concrete plate is received on the slope via multiple jacks, and the height and gradient of the concrete plate can be adjusted by adjusting each jack, and the height of the concrete plate can be adjusted with the jack. By using a simple threaded spacer, the spacer is received by the spacer while maintaining the height and slope of the concrete plate, and then the concrete is opened upward in the space between the whole concrete plate and the slope. It is supposed that the concrete will be filled up to the height of the upper end face of the concrete plate. According to this, it is possible to easily adjust the height and gradient of the concrete plate with a jack before the concrete is put in.
Japanese Patent No. 2618800

    However, in the construction method of the above civil engineering structure, the fluid concrete is applied to the entire concrete board with the introduction of the concrete each time each concrete board is installed. Is in a situation that tends to rise. Especially in the construction of civil engineering structures, it is necessary to secure the strength, and after placing concrete, it is necessary to compact the charged concrete with a vibrator or the like and place the concrete into it. There is a tendency for the force to lift the concrete board based on the above to increase. For this reason, when the concrete board is lifted, the height and posture of the concrete board will be changed from the specified state (regular state), and it is necessary to consider preventing the concrete board from rising during construction. There is.

    In the construction method described above, each time each concrete plate is disposed, concrete is poured into the space between the entire concrete plate and the slope, and the loaded concrete is moved up and down. Bonded at the position near the joint (joint) between the concrete plates adjacent in the direction. However, the timing of concrete injection with the placement of each concrete plate is different, and the joint strength (integrated strength) of each joint part (concrete joint part) should be weakened based on the difference in curing progress rate. I must. For this reason, even if each concrete plate is engaged with the input concrete portion on the back side via an anchor, it is easy to break at each joint portion (concrete joint portion), and each concrete plate is inserted through the input concrete. Thus, it is impossible to expect a relationship that is firmly integrated with each other.

The present invention has been made in view of such circumstances, and the technical problem thereof is the construction of a civil engineering structure that can prevent the concrete board from being lifted and can increase the integrated strength of each concrete board. It is to provide a method .

In order to achieve the above technical problem , the present invention (the invention according to claim 1)
A concrete plate is sequentially arranged from the lower side to the upper side along the slope with a certain distance from the slope, and the concrete is placed between the concrete plate and the slope from the upper side. In the construction method of civil engineering structures
As each of the concrete plates, a floating prevention anchor is provided on the inner surface of each concrete plate between the upper arrangement end surface and the lower arrangement end surface of the concrete plate , and the upper arrangement end surface side of the lift prevention anchor In order to prepare the one having the first and second confirmation holes in order toward the upper arrangement end face side ,
Each time each of the concrete plates is disposed, the concrete is poured in until it is below the upper arrangement end surface of each concrete plate and the lifting prevention anchor is embedded .
At that time, the concrete is introduced so as not to enter the second confirmation hole while entering the first confirmation hole .
As a configuration.

    With the above configuration, each concrete plate is prepared with an anchor for preventing lifting between the upper end surface and the lower end surface of the concrete plate on the inner surface of each concrete plate. Each time a plate is placed, the concrete is poured into the concrete plate at the first level (the topmost) because the concrete is poured below the upper placement end face of each concrete plate until the anchor for anchoring is buried. In the case of (lower stage), the applied concrete acting on the first-stage concrete plate is made smaller than the case where concrete is input up to the upper end face of the first-stage concrete board. If the concrete board is in the second or higher level, the concrete board must be installed. The input concrete to be input is input so as to straddle the concrete plates adjacent to each other up and down, and the acting force of the input concrete can be distributed to the upper and lower concrete plates, and the acting force of the input concrete acting on the upper and lower concrete plates can be reduced. wear. In particular, when the concrete plate is in the second or higher stage, the concrete pressure of the input concrete portion entering the inner surface side (concrete unfilled space) of the lower concrete plate disposed below the concrete plate is The height of the concrete is increased based on the height (depth) of the input concrete. At this time, the anchor for preventing the lifting of the lower concrete plate is inserted into the concrete (hardened). ), And the lower concrete plate maintains the posture of the lower concrete plate, and the lower concrete plate accurately receives the concrete pressure of the input concrete due to the placement of the upper concrete.

In addition, each time a concrete board is installed, the concrete that has been thrown in until the anchor for embedding the lift is embedded is integrated with the anchor for preventing the lift after hardening, and at the bottom of each concrete board. It enters the inner surface of the lower concrete plate and engages with the lower concrete plate. For this reason, the lower concrete slab is put into the concrete that has been put in as the upper concrete slab is placed on the upper concrete board (hardened by entering the inner side of the lower concrete board). Each concrete board will be integrated with each other.
Further, examples of the concrete slab, the upper distribution 置端surface than preventing anchor the floating, in order toward the upper side disposed end face side, providing a having a first, second confirmation hole, said concrete, Since it is configured so as to enter the first confirmation hole so as not to enter the second confirmation hole, it can be lifted simply by looking at the state of the first and second confirmation holes. It can be confirmed that the prevention anchor is embedded in the input concrete, and the input concrete can be prevented from being input more than necessary, and the input amount can be made appropriate.

In the present invention, as a preferred aspect of the first aspect, each of the concrete plates has a height adjuster that can be expanded and contracted on the upper arrangement end surface side of the inner surface of each of the concrete plates. Having the anchor for preventing lifting on the end face side arranged below the tool,
When the concrete is charged, the upper surface after the concrete is charged is configured to have a height lower than the position of the height adjuster on each concrete plate (claim 2). In this preferred embodiment, the height (gradient) of each concrete plate can be adjusted by adjusting the height of the upper arrangement end face side of the concrete plate with the height adjuster, of course, along with the arrangement of each concrete plate. The concrete to be thrown in is embedded with a lower concrete height adjuster disposed under the concrete plate, and the concrete plate is lifted to prevent the concrete plate from being lifted and the height of the lower concrete plate. The concrete adjuster is embedded, and the concrete plate and the lower concrete plate below the union are united through an anchor for preventing lifting, the input concrete (hardened), and the height adjuster. . For this reason, the concrete plates are integrated with each other, and the integrated strength of the concrete plates can be further enhanced.

In the present invention, as a preferred aspect of the first aspect of the present invention, when the concrete plates are arranged, the concrete plates are arranged with respect to the upper arranged end surface of the lower concrete plate arranged below the concrete plates. While engaging the lower placement end face of the plate,
The tip of the height adjuster is configured to abut against the slope while the tip of the anchor for preventing lifting is separated from the slope (Claim 3). In this preferred embodiment, the lower arrangement end face side of each concrete board is engaged (supported) with the upper arrangement end face side of the lower lower concrete board, and the height of the upper arrangement end face side of each concrete board is increased. The height can be adjusted with a height adjuster (the posture (gradient) adjustment of each concrete plate), and the tip of the lifting prevention anchor does not contact the slope during the adjustment. For this reason, the height and posture adjustment of each concrete board can be performed smoothly.

    According to the present invention (the invention according to claim 1), by using the method, it is possible to prevent the concrete plate from being lifted and to increase the integrated strength of the concrete plates.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
In the revetment 1 as a civil engineering structure according to the embodiment, as shown in FIG. 1, the slope 2 faces upward from the river side (left side in FIG. 1) to the land side (right side in FIG. 1). The base block 4 is provided at the lower end position of the slope 2. In the present embodiment, the slope 2 is formed by a mortar layer 5, and the mortar layer 5 is formed by spraying mortar on a bedrock shaped with a predetermined gradient. The foundation block 4 is arranged so as to extend in the flow direction of river water (perpendicular to the paper surface in FIG. 1), and the foundation block 4 is located on the river side as it goes upward in the upper part on the land side. An inclined support surface 4a is formed.

    As shown in FIGS. 1 and 2, a plurality of civil engineering structure units 7 are laid on the slope 2 mainly for the purpose of exerting a revetment function. As shown in FIGS. 1 to 6, each civil engineering structure unit 7 includes a concrete plate 8 as a main element, a height adjuster 9, and a lifting prevention anchor (hereinafter referred to as an anchor) 10. The height adjuster 9 and the anchor 10 are attached to the inner surface of the concrete plate 8. In FIG. 2, reference numeral 40 denotes a beak portion that is hit on site for curve construction.

    As shown in FIGS. 1 to 5, the concrete plate 8 of the civil engineering unit 7 covers the slope 2 with the plate surface, and the concrete plate 8 has a substantially square shape in plan view with a certain thickness. Is formed. One side surface of the concrete plate 8 is a lower side surface 8a, the side surface facing the lower side surface 8a is an upper side surface 8b, and the other two side surfaces are side surfaces 8c. Yes. In the present embodiment, the concrete plate 8 has a thickness of about 130 mm and a side of about 1000 mm.

A pair of recesses (one of the engaged portion or the engagement portion) 13 spaced apart from each other by a predetermined interval is formed on the lower arrangement end surface 8a of the concrete plate 8, and a pair of recesses 13 is formed on the upper arrangement end surface 8b. A pair of protrusions 14 (the other of the engaged part or the engaging part) 14 corresponding to is projected. The pair of recesses 13 are rotatably fitted to a pair of protrusions 14 in adjacent (lower) civil engineering structure units 7, and in the fitted (engaged) state, the fitted parts are As a center, the civil construction unit 7 is allowed to swing slightly in the vertical direction relative to another adjacent civil construction unit 7. Of course, at this time, in this embodiment, the fitting state between the pair of protrusions 14 and the pair of recesses 13 is rotatable while avoiding as much as possible, and the civil engineering structure unit 7 is The concrete plate 8 is prevented from moving in the thickness direction (particularly the upper side).
In the present embodiment, a pair of recesses 13 is used as the recesses 13, but instead, a single recess (long hole) configured so that the pair of recesses are continuously connected is used. Also good.

    As shown in FIG. 3, a recess 15 is formed on the outer surface of the concrete plate 8, and a special lifting bracket (not shown) is locked in the recess 15 so as to be lifted and conveyed. A pin 16 is erected. In this case, when the concrete plate 8 is lifted and conveyed, the position of the lifting pin 16 is the center of gravity of the concrete plate 8 so as to be in a predetermined inclined state (an attitude in which the lower arrangement end face 8b is lower than the upper arrangement end face 8a). To the upper arrangement end face 8b side. On the other hand, as shown in FIGS. 4 to 6, two insert nuts 17 for the height adjuster 9 are embedded in the inner surface of the concrete plate 8 on the upper disposed end surface side 8b, and anchors on the lower disposed end surface 8a side. One insert nut 18 for 10 is embedded. The two insert nuts 17 are arranged in the vicinity of the corners (both sides in the lateral direction) on the upper arrangement end face 8b side, and the insert nuts 18 are arranged in the lateral direction at a position slightly above the lower arrangement end face 8a. (In FIG. 5, left and right direction) It is located at a substantially central position.

As shown in FIGS. 3 to 5, first and second longitudinal grooves 19 and 20 are formed on one side surface 8 c of the concrete plate 8. The first and second vertical grooves 19 and 20 are sequentially arranged toward the upper arrangement end face 8b side, and both of them are located between the position of the insert nut 17 and the position of the insert nut 18. Located between. The first and second vertical grooves 19 and 20 are formed in a substantially semicircular arc shape in plan view, and each vertical groove 19 (20) penetrates between the inner and outer surfaces of the concrete plate 8.
In this embodiment, as shown in FIGS. 3 and 5, vertical grooves 21 are formed in the lower arrangement end surface 8 a of the concrete plate 8 and flat on the four corners of the concrete plate 8. A surface 8d is formed. The vertical groove 21 is positioned between the pair of recesses 13 (see FIG. 5), and the vertical groove 21 also penetrates between the inner and outer surfaces of the concrete plate 8. The flat surface 8d has a shape in which the four corners of the concrete plate 8 are cut off.

    As shown in FIG. 1, the height adjuster 9 is interposed between the upper arrangement end face 8 b side and the slope 2 on the inner surface of the concrete plate 8 to adjust the height (interval) of the concrete plate 8. The height adjusting tool 9 forms a space 43 between the inner surface of the concrete plate 8 and the slope 2. In this embodiment, two height adjusters 9 are prepared to be attached to the two insert nuts 17, and each of the height adjusters 9 is basically as shown in FIG. The screw rod 22 and the cylindrical nut 23 are provided. The screw rod 22 of each height adjuster 9 is attached by screwing one end of the screw rod 22 to the insert nut 17, and the nut 23 is screwed by the other end of the screw rod 22. The amount of protrusion of the height adjuster 9 from the inner surface of the concrete plate 8 can be adjusted by adjusting the screwed state. For this reason, the amount of protrusion of the height adjuster 9 from the inner surface of the concrete plate 8 can be adjusted within a range in which the screwed state of the nut 23 can be adjusted, but when the amount of protrusion is still insufficient, as shown in FIG. The bolt 24 is screwed onto the tip end side (the lower side in FIG. 7) of the nut 23. As a result, the adjustment amount of the bolt 24 in addition to the adjustment amount of the nut 23 is added to the protrusion amount of the height adjuster 9 from the inner surface of the concrete plate 8, and the protrusion amount does not exist in the bolt 24. It can be made longer than the case. Reference numeral 25 denotes a tightening nut for firmly attaching the screw rod 22 of the height adjuster 9 to the insert nut 17.

    The anchor 10 restricts the concrete plate 8 from being lifted by the input concrete based on the engagement with a concrete layer 27 described later. In this embodiment, the anchor 10 is constituted by a bolt, and the anchor 10 is attached to the inner surface of the concrete plate 8 by being screwed into the insert nut 18. In this case, the protrusion amount of the anchor 10 from the inner surface of the concrete plate 8 is set to be shorter than the protrusion amount of the height adjuster 9 in the shortest state. Reference numeral 26 denotes a tightening nut for firmly attaching the anchor 10 to the insert nut 18.

    As shown in FIG. 1, a concrete layer 27 is interposed in a space 43 between the concrete plate 8 and the mortar layer 5 of the civil construction unit 7 spread on the slope 2. In the concrete layer 27, the height adjusting tool 9 and the anchor 10 of each civil engineering unit are embedded, and the height adjusting tool 9 and the anchor 10 are engaged with the concrete layer 27.

    At the four corners of the concrete plate 8 of each civil engineering unit 7 spread on the slope 2, as shown in FIG. 2, the confirmation holes are formed in cooperation with the concrete plates 8 of other adjacent civil structural units 7. 31 is formed. This confirmation hole 31 is defined by a flat surface 8d on the side surface of each corner of each civil engineering unit 7. Further, the first and second longitudinal grooves 19 and 20 of each civil engineering structure unit 7 cooperate with the lateral side surface 8c of the concrete plate 8 in the other civil engineering structure unit 7 to provide the first and second longitudinal grooves 19 and 20. Confirmation holes 19A and 20A are formed, and the longitudinal groove 21 forms a confirmation hole 21A in cooperation with the upper arranged end face 8b of the concrete board 8 in the other civil engineering structure unit 7. In addition, in FIG. 1, the code | symbol 41 shows top end concrete and 42 shows a ground layer.

Such a revetment (civil engineering structure) 1 is constructed as follows.
First, the slope is shaped with a predetermined gradient (for example, 1: 1.5) and the foundation block 4 is installed. When performing this slope shaping, the rock mass is shaped to a predetermined slope, and mortar is sprayed onto the rock mass of the predetermined slope. As a result, a mortar layer 5 is formed on the bedrock. The mortar layer 5 secures a slope 2 with a predetermined gradient and suppresses the slaking. The foundation block 4 is formed by securing an excavation space below the mortar layer 5 and filling the excavation space with concrete, and the foundation block 4 is formed in the direction of the river flow (the surface of FIG. 1). (Vertical direction). The base block 4 is formed with a support surface 4a that stands substantially perpendicular to the upper surface of the mortar layer 5, and the support surface 4a has a first civil engineering structure unit 7-1 at the bottom. Positioning pins 28 for positioning (concrete plate 8-1) are provided.

    Next, as shown in FIG. 9, the first-stage civil construction unit 7-1 (7) is lifted and conveyed to a predetermined first-stage installation position. When the civil engineering unit 7-1 is lifted and transported, a dedicated lifting bracket and a crane that lifts it through the wire W are used, and the civil engineering unit 7-1 is in a predetermined inclined state using them. Is conveyed to the predetermined first stage installation position. When the civil engineering unit 7-1 is transported to the first stage installation position, the lower arrangement end surface 8a of the concrete plate 8-1 is the foundation block 4 while maintaining the lifting state of the civil engineering unit 7-1. The support plate 4a is in contact with the support plate 4a and the end surface 8b of the concrete plate 8-1 is supported on the mortar layer 5 via the height adjuster 9. At this time, the positioning pins 28 of the foundation block 4 are inserted into the pair of recesses 13 on the lower arrangement end face 8a of the concrete plate 8-1, and the positioning on the lower arrangement end face 8a side of the concrete plate 8-1 is performed. Done. However, even in this positioning state, the civil engineering structure unit 7-1 can slightly swing in the vertical direction.

    Next, as shown in FIG. 10, the gradient of the civil engineering structure unit 7-1 in the first stage is adjusted. In adjusting the gradient of the civil engineering unit 7-1, a jack (height adjusting device) 29 is set between the upper arrangement end face 8a side of the concrete plate 8 and the mortar layer 5, and the jack 29 Is used to adjust the distance between the upper arrangement end face 8a side of the concrete board 8-1 and the mortar layer 5 so that the concrete board 8-1 (unit for civil engineering structure 7-1) is a predetermined part of the mortar layer 5. Be graded. Then, after adjusting the height adjuster 9 (nut 23) to support the civil engineering structure unit 7-1 so as to maintain the predetermined gradient, the jack 29 supports the concrete plate 8-1. Is released, and the jack 29 is removed from between the concrete plate 8 and the mortar layer 5.

    In this embodiment, as a safer and more reliable method, an adjustment method using the jack 29 is used. However, by using a fastener such as a monkey for the height adjustment tool 9, the height adjustment tool 9 can be directly adjusted. Elongation may be adjusted. In that case, in order to ensure the safety of the operator even if the height adjusting tool 9 is detached, it is preferable to perform the work by interposing a receiving tool such as a spacer between the concrete plate 8 and the slope 2.

    Next, as shown in FIG. 11, concrete 30-1 is poured into a space 43 between the concrete plate 8-1 and the mortar layer 5 in the first-stage civil engineering unit 7. The concrete 30-1 is charged so that the upper surface 30a thereof is in the range of 1/2 to 2/3 from the lower end face 8a of the concrete plate 8 along the mortar layer 5. Only the anchor 10 is embedded in the input concrete 30-1, and the height adjuster 9 is not embedded in the input concrete 30-1. At this time, the concrete 30-1 is carefully compacted by a vibrator or the like, but the viscosity of the concrete 30-1 is lowered by the action of the vibrator or the like, and the concrete 30- When 1 reaches the position of the first confirmation hole 19A, it enters the first confirmation hole 19A. The worker confirms that the concrete 30-1 has entered the first confirmation hole 19A, stops the concrete 30-1 charging operation, and stops the operation of the vibrator and the like. As a result, the viscosity of the concrete 30-1 increases, the concrete 30-1 stops entering the first confirmation hole 19A, and the concrete 30-1 does not overflow from the first confirmation hole 19A. At this time, the worker also confirms that the concrete 30-1 has not entered the second confirmation hole 20A in order to prevent the concrete 30-1 from being thrown in more than necessary.

    As a result, the concrete 30-1 is placed below the upper arrangement end face 8b of the concrete plate 8-1 and until the anchor 10 is embedded, and the amount of input concrete 30-1 is reduced to the concrete plate 8- Therefore, it is possible to reduce the amount of the concrete up to the upper arrangement end face 8b of 1 and to reduce the acting force of the charging concrete 30-1 acting on the concrete plate 8-1.

Next, as shown in FIG. 12, the second-stage civil engineering structure unit 7-2 (7) is transported to the second-stage installation position. At this second stage installation position, the pair of recesses 13 on the lower end face 8a of the second stage civil engineering unit 7-2 are fitted to the protrusions 14 of the first stage civil engineering unit 7-1. The upper arrangement end face 8 b side of the concrete plate 8-2 (8) in the second-stage civil construction unit 7-2 is supported on the mortar layer 5 via the height adjuster 9. At this time, as in the case of the gradient adjustment of the first-stage civil engineering unit 7-1, as shown in FIG. 13, the jack 29 and the height adjuster 9 are used for the second-stage civil engineering structure. The gradient adjustment of the concrete plate 8-2 in the unit 7-2 is performed, and the upper surface of the concrete plate 8-2 is continuously connected to the first-stage concrete plate 8-1.
When the pair of recesses 13 on the lower arrangement end face 8a of the second-stage civil engineering unit 7-2 is fitted to the protrusions 14 of the first-stage civil engineering unit 7-1, the height is adjusted. It is preferable to shorten the setting tool 9 short. This is because the height adjusting tool 9 is less likely to interfere (contact) with the slope 2 during the fitting operation, and the fitting operation is performed smoothly.

    Next, as shown in FIG. 14, concrete 30-2 is placed between the concrete plate 8-2 and the slope 2 in the second stage civil engineering unit 7-2. This input concrete 30-2 is input into the non-input space 43 between the first-stage concrete plate 8-1 and the mortar layer 5 and is ½ from the lower end of the second-stage concrete plate 8-2. To the position of ˜2 / 3, and in the input concrete 30-2, the height adjuster 9 of the civil engineering structure unit 7-1 in the first stage and the unit 7-2 for the civil engineering structure in the second stage The anchor 10 is embedded, and the height adjuster 9 of the second-stage civil engineering structure unit 7-2 is not embedded in the charging concrete 30b. Of course, at this time as well, the operator confirms the proper charging of the concrete 30-2 through the first and second confirmation holes 19A and 20A.

    Thereby, the acting force of the input concrete 30-2 can be distributed to the first and second concrete plates 8-1 and 8-2, and the input acting on the first and second concrete plates 8-1 and 8-2. The acting force of the concrete 30-2 can be reduced. In this case, the concrete pressure in the portion of the input concrete 30-2 that enters the inner surface side (concrete unfilled space 43) of the concrete plate 8-1 is increased based on the height (depth) of the input concrete 30-2. However, at this time, the anchor 10 in the concrete plate 8-1 is engaged with the concrete (hardening) 30-1 that is put in along with the arrangement of the concrete plate 8-1, and the concrete plate 8-1 is engaged. Thus, the concrete plate 8-1 held in its strong state can accurately receive the concrete pressure of the input concrete 30-2. In addition, the pair of recesses 13 of the concrete plate 8-2 are fitted to the pair of protrusions 14 in the concrete plate 8-1 held in this strong state, so that the concrete plate 8-2 has a thickness direction (particularly upward). The concrete plate 8-2 does not move (raise) due to the acting force of the input concrete 30-2.

    In this case, the input concrete 30-2 straddles the first-stage concrete plate 8-1 and the second-stage concrete plate 8-2. Therefore, after the input concrete 30-2 is hardened, the input concrete 30-2 and the first-stage concrete plate 8-1 are connected via the height adjuster 9, and the input concrete 30-2 and the second-stage concrete board 8-1 are connected. The concrete plate 8-2 is connected via an anchor 10, and the first concrete plate 8-1 and the second concrete plate 8-2 are connected via input concrete 30-2. Will be. At this time, the first-stage concrete plate 8-1 is engaged with the concrete 30-2 that has entered the inner surface thereof, and this action of the first-stage concrete plate 8-1 results in the second-stage concrete plate 8-1. The concrete plate 8-2 is pressed against the slope 2. As a result, based on these actions, the integration of the first-stage concrete plate 8-1 and the second-stage concrete plate 8-2 increases.

    Thereafter, the same operation is repeated for the installation of the civil engineering structure unit 7 in the third and subsequent stages. Finally, the top concrete 41 is formed as the top concrete processing, and the construction work is completed.

Although the embodiment has been described above, the present invention includes the following aspects.
(1) The present invention is not limited to the case of revetment in river 3, but also applies to revetment in lakes and the sea.
(2) One or three or more height adjusters 9 are provided.
(3) Instead of the positioning pins 28, protrusions that fit into the recesses 13 of the concrete plate 8 may be formed on the support surface 4 a of the foundation block 4.
(4) In the embodiment, in order to ensure the construction, the concrete plate 8 provided with the anchor 10 for preventing lifting is used, but the concrete plate 8 may be used without the anchor 10. thing. In that case, a concrete plate is sequentially arranged from the lower side to the upper side along the slope with a certain distance from the slope, and between each concrete plate and the slope. In the construction method of a civil engineering structure in which concrete is poured into the concrete from the upper side, each time the concrete plates are arranged, the concrete is placed so that the height of the concrete is lower than the upper arrangement end face of each concrete board. It will be placed so that it is located between the end faces. As a result, the acting force of the input concrete is received by the concrete plates adjacent in the vertical direction, and the acting force of the input concrete can be dispersed.
(5) Use a plurality of lifting prevention anchors.
(6) Plant natural stones, water purification materials, vegetation bases, etc. on the surface of the concrete board 8.
(7) Use porous concrete for the concrete plate 8 or make the surface of the concrete plate 8 into a pseudo stone shape.
(8) In the embodiment, the slope 2 is formed by the mortar layer 5, but the slope 2 may be formed by using not only mortar but also smoothed concrete, and a rock or the like is firmly formed. If it is a supporting ground, the slope 2 may be formed by itself and the mortar layer 5 may be omitted.
(10) The state of the slope 2 does not necessarily need to be smooth, and some unevenness is allowed.

    It should be noted that the object of the present invention is not limited to what is explicitly described, but includes provision of what is substantially preferable or corresponding to what is described as an advantage.

The longitudinal cross-sectional view explaining the revetment which concerns on embodiment. Explanatory drawing explaining the revetment which concerns on embodiment planarly. The top view which shows the unit for civil engineering structures which concerns on embodiment. The right view which shows the unit for civil engineering structures which concerns on embodiment. The figure which shows the inner surface side of the unit for civil engineering structures which concerns on embodiment. Explanatory drawing which shows the height adjustment tool which concerns on embodiment. Explanatory drawing which shows the deformation | transformation usage aspect of the height adjustment tool of FIG. Explanatory drawing which shows the anchor which concerns on embodiment. Explanatory drawing explaining the construction process of the revetment of gentle slope. Explanatory drawing explaining the process of following FIG. Explanatory drawing explaining the process following FIG. Explanatory drawing explaining the process following FIG. Explanatory drawing explaining the process following FIG. Explanatory drawing explaining the process following FIG.

DESCRIPTION OF SYMBOLS 1 Revetment 2 Slope 8,8-1,8-2 Concrete board 8a Lower arrangement end face of concrete board 8b Upper arrangement end face of concrete board 8d Flat face of concrete board 9 Height adjustment tool 10 Lift prevention anchor 13 Pair of Recess 14 Pair of protrusions 19A First confirmation hole 20A Second confirmation hole 30, 30-1, 30-2 Concrete 30a Concrete upper surface 43 Space

Claims (3)

A concrete plate is sequentially arranged from the lower side to the upper side along the slope with a certain distance from the slope, and the concrete is placed between the concrete plate and the slope from the upper side. In the construction method of civil engineering structures
As each of the concrete plates, a floating prevention anchor is provided on the inner surface of each concrete plate between the upper arrangement end surface and the lower arrangement end surface of the concrete plate , and the upper arrangement end surface side of the lift prevention anchor In order to prepare the one having the first and second confirmation holes in order toward the upper arrangement end face side ,
Each time each of the concrete plates is disposed, the concrete is poured in until it is below the upper arrangement end surface of each concrete plate and the lifting prevention anchor is embedded .
At that time, the concrete is introduced so as not to enter the second confirmation hole while entering the first confirmation hole .
The construction method of the civil engineering structure characterized by this. In claim 1,
Each of the concrete plates has a height adjustment tool that can be expanded and contracted on the upper arrangement end face side of the inner surface of each concrete board, and is used for preventing the lifting on the lower arrangement end face side of the height adjustment tool. Having an anchor,
When throwing the concrete, the upper surface after throwing the concrete is a height lower than the position of the height adjustment tool in each concrete plate,
The construction method of the civil engineering structure characterized by this. In claim 2,
When disposing each concrete plate, the lower arrangement end surface of each concrete plate is engaged with the upper arrangement end surface of the lower concrete plate arranged on the lower side of each concrete plate, and
Bringing the tip of the height adjuster into contact with the slope while keeping the tip of the anchor for lifting to be separated from the slope;
The construction method of the civil engineering structure characterized by this.

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