JP2017078297A - Connected concrete block body for arch bridge structure, and deck-type arch bridge - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an easy-to-manufacture, easy-to-convey and versatile connected concrete block body for an arch bridge structure, which has a high degree of freedom of design, which hardly causes fracture during lifting work, and which prevents blocks at both ends from getting away from an arc line of an arch.SOLUTION: In a connected concrete block body for an arch bridge structure, a group, in which a plurality of arch-stone blocks are integrated together by being connected together by an embedded connecting member, serves as a block group, and the block groups are connected together to wholly serve as a series of integrated connected concrete block body. When the connected concrete block body is lifted to form an arc shape, it can be formed into an arch bridge.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an arch structure of an arch bridge formed by connecting a plurality of concrete blocks into a block group, and connecting a number of the concrete blocks to form a large number of concrete blocks, and a concrete block body used in the construction method, and an upper road using the same Regarding the arch bridge.

  Generally, when an arch bridge is to be manufactured from concrete, it is a large structure, and therefore work is performed on site. First, a scaffold is erected at the site to form a form so as to form the lower and side surfaces of the arch, and appropriate reinforcements are placed inside the structure before placing concrete. And there is also a need to sufficiently cure the poured concrete until it solidifies. Then, since it is a big scale, the construction cost and the construction period become large. However, now that roads have been completed, there is a high demand not only for new bridges but also for replacing old bridges that have already been built. By the way, there are 146,000 bridges of 15m or more, and it is estimated that there are about 840,000 bridges of 15m or less. And it is said that 20% of bridges longer than 15m will reach 50 years in 2016, and 48% in 2016 will reach 50 years. Even in bridges shorter than 15m, It is assumed that the trend for renovation will be similar.

  In bridge replacement work, since repairs are generally aimed at extending the life of the bridge, a durable and strong concrete bridge can suffice as a method that meets the needs. However, the more bridges that are used for daily use, the more smooth replacement work is desired so as not to hinder the use and traffic, so selecting a concrete structure that tends to have a long construction period is not recommended. Not always easy. In addition, as the construction period takes longer, the cost often increases.

  Now, it is known that the structure of the arch bridge was widely used as a stone bridge since the Roman period. The arch structure does not apply a large bending force to each talc member, and most of the vertical load is a compressive force that is transmitted to the fulcrums at both ends. There is an advantage that it is easy to secure the span relatively long. Since concrete is a material that is very resistant to compression, it is a suitable material for an arch structure.

  And if the arch bridge itself can be manufactured as a large-sized precast concrete, it is possible to bring the molded product at the factory to the site and install it, so that the construction process at the site can be simplified. The usefulness of manufacturing arch bridges with precast concrete blocks is high. On the other hand, it takes one week or more after placing, although it depends on the curing temperature, in order to fully exert the compressive stress of concrete. Thus, if the precast block is sufficiently cured, it can be constructed on site with sufficient strength. However, if the arch bridge itself is precast as a whole as a whole, the structure becomes too large and its conveyance becomes difficult. Therefore, even when the block is roughly divided to some extent, it becomes a large block, so that the weight of each block reaches several tons. However, if it is large and heavy, it is not easy to carry out and transport from the factory, and the heavy equipment and transportation means become large, and the height of the arch (compressed height, arch rise) is high. It is difficult to travel on the road, and in reality it is likely to be accompanied by various difficulties. Also, the distance between the ends of the arch (span, span) and the arch rise vary widely depending on the bridge, so it is not suitable for mass production if the precast concrete formwork is made to correspond to it. Therefore, it cannot be said that practical use corresponding to the cost is easy. Therefore, there is a demand for a construction method with a high degree of freedom that is practically compatible with the design of arch bridges such as span and arch rise.

  However, if a concrete block is manufactured with each block in the stone wall part and then piled up one by one like a stonework, the practicality is rather poor. Of course, the degree of freedom in design will be high, but in order to pile up blocks like stone masonry, it is necessary to build up the foundation of the arc of the arch on the span between the fulcrum, etc. Large-scale work is required in advance. However, in order to adopt it as a construction method in rivers, it is difficult to say that it is a practical construction method considering the difficulty of supporting and scaffolding the foundation. The work of stacking blocks in an arch shape without gaps is not only laborious and time-consuming, but if precise stacking is required in the first place, the worker is required to have a skilled skill. Then, as it is a technique that is unsuitable for widespread use in the construction industry as a reproducible and stable general construction method, there is a demand for a building that can be handled more easily and can be constructed more easily. .

  As one of those who aimed for a simpler construction method, Adrian E. Prof. Long divides the arc of the arch into a plurality of inverted trapezoidal talc parts and arranges them in a row on a plane as an arch bridge that forms a plurality of concrete blocks and forms them. After unfolding and arranging them, the upper plane of each talc unit is connected with a series of reinforcing lattice-shaped polypropylene resin, and then transported to the site on the plane, then the central mortar block on the site is A method has been proposed in which the whole is formed into an arcuate arch by being lifted so as to be higher and then installed on the site (see, for example, Patent Document 1 and Patent Document 2).

  Certainly, according to this construction method, a series of talc parts arranged in a line on the plane and connected to the upper plane are transported to the site and then lifted into an arch shape. There is also room for a plurality of arch members to be placed flat on top of each other. And since scaffolding work and support work at the site can be simplified, the construction period at the site can be shortened when compared with the construction of a normal arch bridge.

  In the procedures disclosed in the detailed description of the invention as specific embodiments in these Patent Documents 1 and 2, concrete blocks of talc parts having the same shape are molded one by one in one mold. In addition, a procedure is described in which the blocks of the talc portion are arranged in a line on a plane, and then a lattice-shaped polypropylene resin is reinforced and connected to the upper plane.

  However, according to this method, the series of connected arch bridges will eventually be deployed in a flat state, so large heavy machinery is also required when lifting to transport this series. It becomes. Moreover, it is necessary to lift it with a large heavy machine at the time of installation. That is, if it is integrated as a series from the beginning at the time of manufacture, the conveyance itself becomes a considerably large work. For example, when the span is 10 m and the arch rise is 2.5 m, the total length of the talc block developed on a plane is about 12 m. If the span is 10 m and the arch rise is 4 m, the total length is about 14 m. Because it is long and heavy, it can be safely transported on roads in Japan even if it is flat, unless it is a large trailer. Therefore, it cannot be said that the convenience of being manufactured and transported in a flat state can be fully utilized. In Patent Documents 1 and 2, a span of about 3 to 8 m is disclosed.

  When the blocks of the stone stone part are lifted by a crane, each block of the stone stone part will be suspended while adhering to the adjacent block and the wall surface, so it is assumed that a beautiful arch arc will be formed naturally Has been. However, when trying to reproduce actually, when using an arrangement that draws a deep arc that raises the arch rise, the blocks of the talc parts at both ends that cannot be suspended cannot be in close contact with the adjacent blocks, It has been found that there is a problem in that it hangs in an open state without tilting to a clean arc line of the arch. As a result, there will be a gap and it will be bent outwards, making it difficult to install the blocks at both ends according to the installation span, making it difficult to proceed with the installation work. It is not easy to tilt the block opened in the closed state to a desired position. It was not easy to work with high reproducibility according to the intended span of installation.

  Now, when it is lifted in this way, the phenomenon that the block at the lower end that is suspended does not come into close contact with the adjacent upper stone block occurs because of the rotation due to the positional relationship between the position of the center of gravity of the block and the rotation support shaft of the connecting part This is due to the direction of movement. Here, since a load including a block connected to the lower part of the block suspended from the connecting portion is applied, it is not the position of the center of gravity of the block itself but the position of the center of gravity of the entire suspended part.

  First, since there is a connecting portion with an adjacent block on the upper plane side, the block itself is suspended with the connecting portion as a rotation support shaft. The concrete block of the stone stone part is more than 150kg, so when suspended, it tries to move so that its center of gravity moves vertically below the support shaft while rotating around the connecting part that becomes the rotation support shaft. Rotate. And, if the center of gravity of the block of the scorpion part is located outside the vertical bottom of the connecting part, the block tries to rotate in the direction in contact with the adjacent block, so that it touches the adjacent block without a gap. Thus, a clean desired arch line is naturally formed by simply lifting it up.

  However, if the arch rise is increased when the span is constant, the curvature of the arc increases, and the upper plane of the block on the lower end side is greatly tilted. When the block is rotated so that the center of gravity is below the vertical line, the block is separated from the adjacent upper block, and the lower end block is bent in the opposite direction without forming a clean arch line. It becomes like this. Then, it cannot be stably placed on the desired span position in the lower end portion, and when drawing an arch with a high arch rise and a large curvature, there is a disadvantage that the lower end block is not properly accommodated.

  Furthermore, when the arch structure is connected in series and lifted at a stretch, when using polypropylene resin for the connecting member as described in Documents 1 and 2, it tends to stretch without being able to withstand the load, and if stretched, Since the blocks are shifted and stacked, it becomes difficult to form a beautiful arch. Because, if the concrete block of the stone stone part has a width of 1 m, the weight of about one block will be 150 to 180 kg, but a total of 10 to 20 pieces of stone stone part blocks are connected in total. Because it will be. Practically, the connecting member will be stretched under load, so that it is easy to limit the increase of the span.

International Publication No. 2004/044332 US Pat. No. 7,204,058

  Now, as described above, the conventional construction method of the arch bridge described in Patent Document 1 divides the arch into a talc block and spreads the concrete blocks in a row as if they were developed in a plane. This is an arch bridge construction method in which the upper parts of the talc blocks are connected with polypropylene resin and then installed so that they are lifted and curved into an arch shape. However, when suspended in the arch shape, there is a problem that the block at the lower stone side that is suspended does not draw an arch-shaped line and is bent between the adjacent blocks. This is caused by the movement of the center of gravity of the suspended block, and in the block at the lower end where the curvature of the arc is large, when moving the center of gravity toward the lower extension of the connecting part, the arc of the arch is in contact with the adjacent block. Rather than forming the shape, it rotates in the opposite direction, so that it bends backward and opens as if the lower end of the arch was bent.

  However, in the arch bridge, a compressive load is applied toward the lower end side blocks at both ends, so the lower end block is a very important block and is required to be appropriately positioned in the line shape of the arch. . These lower-end blocks cannot be landed on the ground while bent in the opposite direction, but the lower-end blocks that are suspended from adjacent blocks have their own weights, so they can be easily desired after lifting It cannot be pushed back in the direction. Therefore, it is not easy to increase the arch rise having a large inclination that causes the lower end block to bend in the opposite direction or to increase the span.

  Moreover, the block of the stone stone part used by such a construction method is a block with a thickness of 20-30 cm, for example, Comprising: The polypropylene resin which connects the upper surface side is embed | buried under an upper plane with mortar etc. In this case, considering the adhesion to concrete, it is conceivable that the connecting member is covered with a thin mortar on the upper plane. Then, the initial state and the final state, such as a state where the talc blocks are lined up in a row in a flat state, and a completed state in which the talc blocks are lifted and contacted with each other to form an arch-shaped arc correctly, are final. In the state, the following problems will not be revealed, but if the lower end block opens in the reverse direction during the lifting process, the upper end of the talc block will come into contact with the upper end of the adjacent block, resulting in chipping. , Cracks are a problem. Furthermore, depending on the degree of loss, the adhesion of the reinforcing member embedded inside to the concrete may be reduced. In particular, when it is placed in two stages, the adhesion of the concrete is not necessarily good at the top and bottom of the reinforcing member, so by placing the upper end, it is above the reinforcing member embedded inside The mortar may float and peel off as a whole. Further, if the entire surface layer is lifted by the force applied to the end portion, the strength is remarkably reduced at the embedded reinforcing member. Then, it becomes a problem that may lead to a significant loss of articulation strength, and it is concerned with the safety of suspension beyond the level of mere aesthetics.

  And, in the lifting process, for example, when a number of connected blocks of flat stones are lifted in order from the center with a crane, the middle becomes higher in an arch shape while being lifted. The blocks on both sides that are connected to are still flat. Then, an S-shaped curve in which the arcuate arch curve is curved in the reverse direction is drawn. Now, the block warps to the opposite side near the plane because of the block that touches the ground among the blocks of the talc block and the block that is lifted next to it, the block of the spar block moves in the direction of the center of gravity This is because it cannot be rotated in an appropriate direction. In other words, not only when the arch rise is high, but also when the center is simply lifted, the upper ends of adjacent blocks are raised above the connected part, and the contacted end may be chipped or cracked. It will be easy. Thus, there is a demand for a device that prevents the end portion from being lost due to the movement of the block during the operation of lifting the connected arches.

  By the way, the blocks of the talc unit that are juxtaposed in a row on a flat surface have a large overall length and a large weight, so that it is inevitable to carry out and transport to the site, which is inevitable when manufactured with precast concrete. In addition to the increase in the size of heavy machinery and trucks used for transportation, the demand for the skill level of workers during construction increases, making construction difficult. Therefore, a construction method more suitable for carrying out / conveying is required.

  In addition, after placing blocks in parallel on the flat surface and arranging the connecting members on the upper flat surface of those blocks, a series of long and large molds are prepared. Either make the whole in one piece, or place the blocks in the upper stone as a series after placing them in parallel after placing the blocks in the stone stone part individually with the formwork. After that, it is assumed that the second stage will be placed.

  However, in the case of placing the whole in a series as in the former procedure, it becomes necessary to prepare several types of molds for the mold. The span of the arch and the height of the arch rise vary according to the individual bridges and are not uniform. Therefore, general-purpose production is not possible, and the advantage of being precast is lacking. In the latter case, there are many procedures such as twice placing work, and a structural method that can be further simplified is desired.

  Therefore, the problem to be solved by the present invention is to form a mortar block with a concrete precast block in order to apply an arch structure that piles up calcite that can obtain a strong and stable arch structure using a compressive load in an arc shape. In addition, the blocks can be lifted as a series by connecting the upper surface of the outer peripheral side in a state where they are arranged in parallel on a plane, and the arc is drawn by lifting them so that the central part is highly curved The arch bridge is made of a portable precast concrete block that can be formed into an arch bridge, and the lower mortar block suspended during the lifting operation is opened without touching the adjacent mortar block. The lifting operation can be appropriately performed by the arc shape of the arch so as not to be damaged.

  Also, when a series of talc blocks are raised in order from the center by lifting, the lower skirt part curves to draw an S shape in the direction opposite to the curvature of the arc of the arch. May bend in the opposite direction to the arc of the arch. Then, since the possibility that the upper end of the talc block will come into contact with the adjacent talc block increases and it is lost, it is to make it difficult to be lost.

  Now, if a series of blocks forming the arc of the arch bridge are formed continuously and integrally, they are long and heavy, and it is difficult to carry out and transport to the site after integration. Therefore, in order to make manufacturing, carrying out, and carrying easier, it will be examined whether it is possible to carry out in a state where it is divided into a plurality of block groups composed of several blocks, for example. However, in order to combine and integrate the block groups divided into several groups, it is necessary to connect the block groups after transportation. However, the stone blocks at each end of a plurality of groups are connected and integrated. It is not easy to make it. For example, if it is necessary to add blocks for combining the blocks after transporting and connecting them at the site, it will not be possible to lift them unless they are cured for several days. As a result, the benefits of making a precast product are diminished. In the first place, if the connecting member can only be circulated only between the end blocks, it is not easy to secure the adhesion strength enough to hold the load applied to the connecting member, and the connecting itself is practical. It becomes difficult to give a strong strength. Thus, dividing into a plurality of block groups giving priority to the convenience of conveyance is not a means that can be easily implemented in consideration of subsequent connection, and further practical devices are required.

  Therefore, a further object of the present invention is to make it easy to transport blocks of the arch bridge's talc section as a plurality of block groups, while allowing the transported block groups to be connected together and lifted together, so that the arch It is an object of the present invention to provide a device that can form an arc properly and that can be stably suspended by forming an arc at a desired position without shifting the suspended block.

  The means of the present invention for solving the above-mentioned problem is that, in the first means, the left and right oblique sides, the lower side and the upper side parallel to the lower side and the upper side having a length longer than the lower side are used as the bottom surface. A plurality of square pillar-shaped talc blocks that are perpendicular to each other are arranged in parallel in the extending direction of the upper side of the inverted trapezoid in such a direction that the side surface of the square column that contacts the lower side of the inverted trapezoid is the lower plane and the side surface that contacts the upper side is the upper plane. Arranged so that they are placed side-by-side, and connecting members are buried in the vicinity of the upper flat surface, and the adjacent mortar blocks and the mortar blocks that hang downward are pivotally connected around the connection point. The block group in a state of being made into a single unit by connecting multiple groups, and when the whole is lifted, an arch bridge that can be formed into an arcuate arch bridge with the lower side as the inner circumference and the upper side as the outer circumference Articulated concrete block for bridge structure It is a body.

  For example, after connecting four or five square pillar talc blocks as one group, preparing multiple groups of these blocks, transporting them to the site, connecting them in groups of about five groups. Then, it is lifted and formed into an arcuate arch bridge. By dividing, it is not necessary to use special heavy equipment and trucks for carrying out and transporting, so that the work load and difficulty of skill can be reduced and the cost can be reduced. The connection of the divided block groups is realized by integrating the adjacent talc blocks by arranging the eccentric washer fasteners on the upper surface so that the arch shape can be formed properly when lifting. Can be made. In this case, if the plate of the eccentric washer is a flat plate, the plate can be bent. Therefore, it can follow the change in the angle of the upper plane that occurs when the talc blocks are lifted from the plane.

  The connecting member is, for example, a flat sheet-like member having an open space, a member having good adhesion to concrete and high tensile strength, such as a lattice-like high-strength plastic resin, carbon fiber, glass fiber, Examples thereof include a plastic resin lattice material reinforced with a core material such as polyester or aramid fiber, a net-like or mesh-like stainless steel wire, a hard rubber mesh material, or the like. Among them, as a means for connecting members, it is one of simple and preferable methods to use a geogrid used in civil engineering work for the purpose of connecting concrete blocks to each other. By connecting a single geogrid so as to be embedded over a series of concrete blocks, functions that are not used in terms of embankment reinforcement, which is the purpose of normal geogrids, can be demonstrated. It will be a thing. The geogrid is a member made of a sheet-like polymer material having a regular lattice structure in which components having tensile resistance are connected as defined in JIS L0221 (geo-synthetic term). . For example, it is a grid-like member made of high-density polyethylene resin. And it is preferable to use what was further reinforced by arranging the core of an aramid resin suitably in the inside. Specifically, as a geogrid on which an aramid resin core material is arranged, for example, Adem made by Maeda Kosen can be mentioned. Since Adem HG-200 has a tensile strength of quality control strength of 200 kN / m, if it is buried near the upper flat surface of the talc block when placing concrete, the load on the block when lifting as a connecting member Can withstand arch formation.

  Next, a number of talc blocks are arranged in parallel, as if the arcs on the side of the arch bridge are finely segmented and deployed in a plane, and a large number of inverted trapezoids are arranged in a plane. Since the talc block is connected with the adjacent talc block by the geogrid of the connecting member, when lifting with 1 to 3 wires so that the central talc block is located high, By simply tilting and lifting so that the stone stone blocks come into contact with each other, the arc of the arch is drawn naturally. In addition, when the central block is stabilized as a key stone, it is desirable that the number of stone blocks is an odd number. For example, the number of blocks is about 17 to 25.

  In addition, since the number of talc blocks can be separated by cutting the connecting member (for example, geogrid) at the upper flat part which is the location where the adjacent talc blocks are connected, the number of blocks connected is adjusted. It is possible. As mentioned above, the geogrid is looped vertically and horizontally as a whole, but it generates strength on the whole surface, and it has a depth of several centimeters on the upper plane so as to be integrated with the stone block. It is laid and placed so as to be buried there. Since it has a lattice shape, concrete flows into the gap and solidifies to form a block that is integrated with the upper and lower parts, and functions as if a reinforcing member is arranged inside.

  Further, the second means of the present invention for solving the above-mentioned problem is that the side ridge is formed on the bottom of an inverted trapezoid consisting of left and right oblique sides, a lower side and an upper side which is parallel to the lower side and is longer than the lower side. The rectangular pillar-shaped talc block is an orthogonal square-shaped talc block that is divided into two equal parts from the top of the inverted trapezoid to the bottom. When the block is the right end block, and the one with the vertical plane on the left side is the left end block, about 1 to 4 talc blocks are arranged between the left end block and the right end block. One end of the adjacent block group in a state where the connecting member is buried so that the adjacent mortar block and the mortar block suspended downward about the connecting point are pivotally connected. The block By connecting multiple groups of blocks so that the vertically split surfaces face each other, they are integrated into a series, and when the whole is lifted, the arcuate arch bridge has an inner periphery on the lower side and an outer periphery on the upper side. It is an articulated concrete block for arch bridge structure that can be formed.

  In this means, the blocks at both ends of the block group are connected to each other using a half-size block obtained by dividing the scoishi block. Prepare a half-body block that halves the talc block from the upper side to the lower side of the inverted trapezoidal shape. The block group is integrated on site by connecting the adjacent block group and the vertically divided faces facing each other. And in the connection of adjacent block groups, the half-body blocks facing each other are integrated by, for example, fixing the left end block and the right end block using a bolt and an eccentric washer so that the longitudinally split surfaces are in close contact and tightened. I am letting.

  To fix with an eccentric washer, when inserting bolts into the left and right blocks from the left and right holes of the base plate and fastening them, attach an eccentric washer with an eccentric bolt insertion hole attached to one of the bolts. By rotating the washer and pushing it out in the proximity direction in which the space between the bolt shafts is narrowed, the concrete blocks are brought into close contact with each other so that the distance does not increase. Protrusions of abutting portions that resist the pressing force generated when the eccentric washer is rotated are provided at the plate end, and the rotating eccentric washer is regulated so as to be in close contact.

  Furthermore, the third means of the present invention for solving the above-mentioned problem is that a left bolt hole opened in the upper plane of the left end block is connected to the vertically divided surfaces of the left end block and the right end block facing each other. And a right bolt hole opened in the upper plane of the right end block opposite to this, a metal plate with a U-shaped cross section provided at both ends is placed and placed, and each of the left and right sides penetrated by this plate is placed. One of the pilot holes corresponding to the bolt holes is a round hole and the other is a long hole. The long hole is a long hole that opens from the position corresponding to the bolt hole toward the round hole side. The disc-shaped washer set on the top is an eccentric washer having an insertion hole opened at a position eccentric from the center of the disc, and the eccentric washer that contacts the outer diameter of the disc of the eccentric washer rotates. Sometimes the counter plate that gives the pressing force is on the plate And it is provided a connecting concrete block member for arch bridge structure according to the second means.

  In the second and third means, prepare a half-body block that divides the talc block vertically in half, and arrange one to several regular talc blocks in one end to form a group of blocks. The block group is integrated on site by connecting the adjacent block group and the vertically divided faces facing each other. The opposing half-body blocks are integrated by using bolts and eccentric washers to fix the left end block and the right end block so that the vertically split surfaces are brought into close contact and fastened.

  To fix with an eccentric washer, when inserting bolts into the left and right blocks from the left and right holes of the base plate and fastening them, attach an eccentric washer with an eccentric bolt insertion hole attached to one of the bolts. By rotating the washer and pushing it out in the proximity direction in which the space between the bolt shafts is narrowed, the concrete blocks are brought into close contact with each other so that the distance does not increase. Since the protrusion of the opposing plate that resists the pressing force generated when the eccentric washer rotates is provided at one end of the plate, the block that faces the block while the bolt moves in the long hole by regulating the rotating eccentric washer Press to the side to make sure they are in close contact with each other.

  The base metal plate is made of a slightly thick steel, and a rib having a U-shaped cross section is raised on the outer edge of the plate in the direction orthogonal to the connecting surface. Because of the ribs, the plate does not bend easily when a load is applied. Therefore, the plate is not bent along the connection surface, and the connection can be stably performed. On the other hand, when a flat plate is used for a simple eccentric washer, it can be tightened in a flat state, but if it opens in the opposite direction when it is lifted, the plate will be bent.

  Of course, when the vertically split planes that are split in half are connected to each other, the wedge-shaped gap does not occur in the lower part even if connected on a flat surface, unlike the connection of the talc blocks. Sometimes we do not plan to change the angle of the upper plane, so unlike the connection of the scorpion blocks, there should be no need to use plate deformation. However, when connecting in a scene close to the lower end, it is difficult to place the center of gravity closer to the center of the arc than the connecting part because the inclination of the arc is tight, and a force to rotate by its own weight is applied. There is a case. Then, even when the vertically divided surfaces are in contact with each other and are connected to each other, when they are lifted, they are bent in the opposite direction by the movement of the center of gravity and open outward. In that case, if it is a normal flat plate, it will bend and lose a load. Therefore, it is necessary to reinforce the plate itself so that the connecting surface does not open outward. As described above, reinforcing the ribs on the plate itself is a simple method as a countermeasure against outward bending.

  According to a fourth means of the present invention for solving the above-mentioned problem, in the connection of the blocks in the block group by the connection member, the connection member arranged in the longitudinal direction on the connection surface parallel to the upper plane is the block group. The connecting concrete block for an arch bridge structure according to any one of the first to third means, characterized in that the end of each block is embedded in concrete deeper than the connecting surface. Is the body.

  When a plurality of blocks are combined into one block group, and the plurality of block groups are combined and integrated into an articulated concrete block body that is used for the arch bridge structure, one block group is composed of about 5 talc blocks. For example, a geogrid is embedded in the inner surface near the upper plane as a connecting member in the horizontal longitudinal direction parallel to the upper plane. Since the geogrid merely connects the blocks in each block group, the geogrid of the connecting member is interrupted when viewed from the whole arch bridge. Then, the blocks at both ends of the block group, including the load of another block group below, are applied, but the connection point of the end block is the end if the adhesion between the geogrid and the concrete is weak. It can happen that the geogrid is pulled out of the block and falls off. Since the geogrid is buried in the concrete near the upper plane that becomes the connecting surface, for example, at a depth of 3 cm, the geogrid easily falls off if pulled from a direction almost parallel to the connecting surface. Therefore, for the sake of completeness, the end of the geogrid of the connecting member arranged at the end stone blocks at both ends or the vertically divided end blocks is placed near the upper plane which is the connecting surface of the geogrid. By bending in a direction deeper than the embedding depth inside the block, it can be more difficult to come out.

  Specifically, the end of the geogrid is bent 90 degrees downward, is further folded 90 degrees and folded back into a U-shaped cross section, or the end of the geogrid is bent downwardly in a round shape. By doing so, the adhesion strength of the geogrid in the end block is increased, and the geogrid is difficult to come off even if it is pulled. When placing each concrete block in a block group with a single formwork, run the concrete downward and place the geogrid end so that it is bent below the end block. Further, by placing concrete several centimeters further upward, a block group in which the blocks are connected can be obtained. Note that a metal pin or the like may be arranged at the end of the geogrid that is deeply submerged to make it more difficult to remove.

  The fifth means of the present invention for solving the above problem is that the connecting members arranged in the longitudinal direction on the connecting surface parallel to the upper plane in the connecting of the blocks in the block group by the connecting member, The connecting concrete block body for an arch bridge structure according to any one of the first to fourth means, wherein a locking pin orthogonal to the connecting surface is arranged.

  Since the blocks at both ends are easily removed from the connecting member, the connecting member is detached from the concrete by driving a locking pin into the end of the connecting member in a direction perpendicular to the connecting surface and embedding it in the concrete. This prevents the omission. This locking pin is, for example, a U-shaped metal pin or the like, which is driven into a gap between lattices such as a geogrid during driving so as to penetrate the connecting surface, and is embedded and fixed as it is. Even in blocks other than the blocks at both ends, the blocks can be arranged so as to be orthogonal to the connecting surface as appropriate, and the adhesion strength between the connecting surface and the concrete is complemented, and the occurrence of displacement and omission is prevented. .

  The sixth means of the present invention for solving the above-mentioned problem is to adjust the opening degree of the wedge-shaped gap formed between both the talc block or the end block and the talc block adjacent thereto. An articulated concrete block body for an arch bridge structure according to any one of the first to fifth means, wherein a constraining member is provided.

  When the connected concrete block bodies are lifted in an arch shape with a crane so that the center becomes high, when the arch rise is high, the arc is greatly curved near the lower end, so that the inclination becomes tight. Then, when the arch is drawn, if the center of gravity of the lower-end talc block suspended from the connected part is rotated so that it is vertically below the connected part, the suspended pestle block moves outward. It is possible that a gap between adjacent blocks is greatly opened in a wedge shape. Therefore, when lifting, restraint between the stone block near the lower end and the adjacent stone block so that it does not open more than the flat position with a restraining member, and further adjust the opening of the restraining member Then, the wedge-shaped gap is narrowed along the arc of the arch and finally brought into contact with the adjacent block, and then placed on the foundation block at an appropriate intended span position.

  The restraining member connects the lower part of the talc block and the lower part of the adjacent talc block, and is a device that can adjust the tension using a screw or a spring. At the time of placing, it is connected by a geogrid that is closely fixed and placed inside the upper plane, and the talc block on the side that hangs down with the connection point as the rotation axis rotates, so a gap is formed in a wedge shape However, it can be led to a desired arch shape by eliminating the gap. In other words, the wedge-shaped gap is narrowed when suspended by hanging the restraint member between two adjacent blocks so that it does not open too much than the initial state and further adjusting the screw condition. Finally, the formation of a desired appropriate arch arc can be guided.

  The restraining member can be used for restricting between adjacent talc blocks, in addition to being provided between the end talc blocks and the adjacent talc blocks. Both the initial state of flat placement and the completed state in which the arch is drawn in an arc are stable, but the wedge-shaped opening may be larger during the lifting than in the flat state. And since the sheet-like connecting member (for example, geogrid) which is circulated so as to be buried in the surface layer portion of the upper surface of the Sakoishi block is covered with a concrete block having a depth of about 3 cm at the time of placing. The connecting member serving as the fulcrum to be rotated is positioned slightly deeper than the upper plane itself. Then, if it rotates in a direction in which the wedge-shaped opening becomes larger than the flat placement state in the placed state, the end portion on the upper plane side becomes an adjacent talc block, and it is chipped or cracked It will be.

  In order to avoid such a deficiency, it is possible to deal with such a deficiency by arranging a restraining member in preparation for a posture change during lifting. In addition, when it is lifted in order from the center part, the center side is inclined in the direction of drawing an arc, but the part close to the ground at the beginning of lifting becomes a part that tends to bend in the reverse direction, and the end part of the upper plane is not Defects are likely to occur. And if the concrete stuck to the periphery of the connecting member embedded near the surface of the upper plane is cracked and peeled off at the connecting member, the connecting strength will be extremely reduced. This greatly affects safety. Therefore, it can be regulated in advance so that these talc blocks do not open too much in the reverse direction.

  The phenomenon that opens when suspended by the center of gravity is that even when the divided block groups are connected together, the wedge-shaped gap at the time of standing on the plane is not closed by moving the center of gravity when the lower block is lifted It will open. Therefore, as a restraint member, when the restraint member such as a turnbuckle is passed between two adjacent blocks so that it does not open too much than the initial state, and further by adjusting the screw condition, when suspended By narrowing the wedge-shaped gap, it becomes possible to finally lead to formation of a desired appropriate arch arc. Thus, a turnbuckle is suitable as the restraining member.

  A turnbuckle, as specified in JIS A5440 (architectural turnbuckle), has a turnbuckle bolt screwed into the turnbuckle body and the fuselage frame, one with a right-handed screw and the other with a left-handed turnbuckle. There is a restraining member that can adjust the tension at both ends by rotating the body frame of the turnbuckle body and changing the interval between the screw rods. By rotating the fuselage frame of the turnbuckle body by turning the screw cut on the screw rods of the left and right turnbuckle bolts in the opposite direction, both the left and right turnbuckle bolts can be tightened at once. Therefore, the wedge-shaped separation distance between adjacent talc blocks can be shortened appropriately and with a simple operation. Therefore, for example, in a flat state, apply a minimum tension so that the wedge-shaped gap does not widen any more when lifting, and when it is lifted, turn the turnbuckle barrel and tighten it gradually. If you do, you can finally close the spar blocks by eliminating the wedge-shaped gaps, and draw the desired arch-shaped arc. Can be put.

  After the turnbuckle is placed on the foundation block in the arched state, it can be removed as appropriate. The talc block that is arched on the foundation block itself is pressed firmly by compression, so it is necessary to consider that there is no gap even if the lower end block is not guided from the outside. Because there is no. A restraining member such as a turnbuckle is required in preparation for a case where the gap is tilted in the direction in which the gap is opened when the posture of the talc block is lifted during the process of lifting. Since the arcs in the flat state and the completed arch shape at the beginning of manufacture are all in a stable state, there is no need to restrain them with a turnbuckle after the stable state is reached.

  On the other hand, in the lifting process, the connecting member (for example, geogrid) is buried under the surface layer of the upper plane, so that the rotation fulcrum is deepened by that amount. There is concern about loss due to contact. In addition, since the geogrid is buried, depending on the adhesion strength in the vicinity of the geogrid, concrete may be peeled off or cracked around the geogrid, which may have an effect other than physical defects at the edges. Therefore, the turnbuckle can be widely used not only for the lower end block but also for restricting adjacent blocks.

  According to a seventh means of the present invention for solving the above-mentioned problems, any one of the first to sixth means is characterized in that the upper corners of the block are chamfered upward from the connecting portion. It is the connection concrete block body for the arch bridge structure of description.

  A geogrid, which is a connecting member, is buried at a depth of several centimeters below the surface of the upper surface of the Sakoishi block, and the adjacent block can rotate with the geogrid at the connecting part as a fulcrum. However, when turning in the opposite direction so that the wedge-shaped opening opens larger than the state where it is laid flat on a flat surface, the end of the upper plane is adjacent to the stone block or the vertically divided end. It may be in contact with the upper corner of the block and is easily lost. Therefore, if the top edge of the inverted trapezoid is chamfered in advance by chamfering the upper end from the connected part where the geogrid is arranged, a relief that is difficult to be lost even if it rotates in the reverse direction is provided. I can leave. Thereby, even when the block at the lower end is rotated in the opposite direction due to the movement of the center of gravity, it is possible to avoid troubles such as cracking, chipping and peeling of the upper plane end. Even when these divided block groups are combined to form a series, unnecessary deficiencies can be avoided if the upper corners of each block are chamfered in advance.

  In addition, during the lifting operation, the connected stone block may be tilted in the opposite direction when it is lifted from the ground so as to be bent in an S shape. Therefore, since chamfering is difficult if chamfered in advance, the lifting work can be performed without worrying about the chipping at the upper end of the block without fixing the blocks in the middle of lifting with the restraining members. Thereby, if it is rotation of the grade which copes with the behavior which becomes S shape, the effort which restrains each block with a restraint member can be saved. By using this means in combination, it is possible to mainly limit the scene using a restraining member such as a turnbuckle to the phenomenon of opening due to the movement of the center of gravity of the block at the lower end. It becomes easy to simplify. It should be noted that neither the block placed on the flat surface nor the completed arch are in contact with each other, and this phenomenon is manifested only in the lifting process. Chamfering is an important means for solving this problem.

  An eighth means of the present invention for solving the above-mentioned problem is an arc-shaped arch formed of a connecting concrete block body for an arch bridge structure according to any one of the first to seventh means, and This is an upper arch bridge with a horizontal upper road arranged above.

  The articulated concrete block body is an upper arch bridge provided with an upper road that becomes a horizontal passage at the upper part using an arch formed by lifting and having a high center. The arch structure sequentially transmits the load from the top to the adjacent blocks, and can reach the both ends of the arch to form a very solid arc. Even if it is integrated with concrete that is placed from the base to the height of the upper road while being placed on the base block of the base that is the member that supports both ends, the arch can handle the load sufficiently Yes. Therefore, when these connected concrete block bodies are used, it is possible to easily form an upper arch bridge.

  When 4 to 5 blocks are connected as a group of blocks, and these groups are connected and integrated, it becomes easier to manufacture each group with a formwork at the factory. Easy to convert. Also, since multiple block groups are combined, variations in the overall arch rise and span can be obtained by changing the combination pattern. Therefore, it is much better to make one group as a unit than to manufacture all blocks as a unit. In addition, versatility is improved by mold manufacturing. In addition, since the size of one group is small and light, it is easy to carry out and transport after molding, and the work load is reduced. Therefore, it is easy to use including storage.

  Furthermore, when a block group in which blocks that are divided into two parts by dividing the Sakoishi block vertically are arranged as a group of blocks, the end blocks are connected to each other on a plane. It is made so that the vertical planes face each other. Since they can be connected in close contact with each other, the connecting portions are lifted up in an integrated state, and can be strongly fixed as compared with the case where they are connected only by the connecting members.

  Furthermore, the plate is passed over the blocks of the connecting part, bolts are inserted into the left and right holes, and at least one bolt is pressed against the other bolt side by the eccentric washer with the opposing plate on the plate. Thus, a sufficient binding force can be easily obtained while the surfaces of the opposing blocks are more closely attached.

  Of course, if it is a flat plate, it can be tightened in a flat state, but if it opens in the opposite direction when it is lifted, the plate will be bent, making it difficult to open. For this reason, it is difficult to bend outwardly by providing ribs on the left and right sides of the plate plate to make it difficult to bend.

  Furthermore, when the block group is connected, the geogrid of the connecting member of the end block is easily dropped. Therefore, the geogrid is not arranged as a connecting member only on the plane of the connecting surface, but the end is bent toward the inside of the block. Then, it becomes difficult to come off against the pulling in the direction of the connecting surface, and the block at the end is hard to come off. Therefore, since the suspension is more stable, the lifting operation can be performed safely, and the remaining capacity of the number of blocks that can be suspended increases, so that a large span can be easily realized.

  In addition, if the locking pin is driven in a direction orthogonal to the connecting member, the connecting member is less likely to slip on the connecting surface, so that the adhesion strength of the concrete is complemented, and the connecting member is less likely to slip out of the concrete, The end block is difficult to fall off.

  By connecting adjacent blocks with a restraining member so that the wedge-shaped gap does not open more than when flatly placed when lifted, the upper ends of adjacent blocks are clogged, causing cracks or defects, or connected parts Thus, it is possible to avoid the occurrence of a situation such as peeling or dropping of the block from the connecting member. And if it adjusts to the direction which narrows the opening degree of a clearance gap and it closes, since adjacent blocks can contact | adhere, it becomes possible to draw an arch-shaped circular arc appropriately in the suspended state. Therefore, when connecting adjacent blocks by placing a restraining member, even if they are blocks that naturally open in a suspended state, an arched arc can be drawn appropriately, so as desired Thus, it is possible to easily and safely perform the installation work by forming the arch.

  Furthermore, when the restraint member is a turnbuckle, the left and right turnbuckle bolts can be operated at once by rotating the turnbuckle barrel, so that the distance between the screw rods, that is, the wedge-shaped opening, can be adjusted efficiently and easily. Can be safely closed and the blocks can be brought into close contact. And since this can be removed after installation work, it does not cause trouble in the function and aesthetics of the arch bridge.

  Also, the corners on the upper side of each block, that is, the corners above the geogrid of the connecting member embedded in the vicinity of the upper plane are chamfered, so that contact with adjacent blocks can be avoided. As a result, it is difficult for cracks, cracks, and separation to occur, and the risk of the block falling off from the geogrid can be reduced. In the middle of lifting the connected blocks, the block close to the ground surface is curved in the opposite direction (in the direction in which the wedge-shaped opening widens), and an S-shaped curve is drawn from the center. Since the risk of block hitting can be reduced in advance, the process can be simplified during lifting work, making it safer and easier to handle, and constraining blocks that open greatly in the opposite direction, such as blocks at both ends Except for the case where a turnbuckle is used in some cases, the lifting operation can be carried out sufficiently safely by chamfering.

  When the connecting concrete block body of the present application is formed in an arch shape and the upper road is further provided on the upper side, the upper arch bridge can be obtained easily and easily in a short time.

It is the figure which showed the connection concrete block body for arch bridge structures connected as a series from the side as an embodiment. (A) shows a state of being flatly placed on a plane, and (b) shows a state of being arched by lifting. It is the figure which showed the connection concrete block body for arch end structures which connected and integrated the some block group from other sides as other embodiment. (A) shows a state of being flatly placed on a plane, and (b) shows a state of being arched by lifting. An example of a block group using divided blocks at both ends is shown. It is a figure which shows an example of an eccentric washer and a plate with a rib. It is an enlarged view of the part which connects the divided blocks with the vertically divided faces facing each other with an eccentric washer. It is a figure which shows an example of arrangement | positioning of the grid of a geogrid, and a connection location. It is a schematic diagram of the connection state of the grid of a geogrid to be embedded and a block group. It is a figure which shows a mode that the geogrid is laid and arrange | positioned in a block group. It is a figure which shows placement of the block group by a formwork, (a) It is a figure which shows the metal mold | die for forming a wedge-shaped clearance gap, (b) is the figure which poured concrete to the vertex of the wedge shape. It is a figure which shows the placement of the block group by a formwork, (c) showed a mode that the geogrid was mounted from the top immediately after pouring concrete downward, and also the formwork for chamfering parts was mounted on it. It is a figure and (d) is a mode of the formwork just before adding concrete to a geogrid. It is the schematic diagram which showed that the width | variety of the inner span of the connection concrete block body for arch bridge structures, and the height of an inner space were fluctuate | varied when the length of the lower side of a talc block was changed. It is process explanatory drawing which illustrated an example of the operation | work process which mounts the connection concrete block body for arch bridge structures on a foundation block, casts the circumference | surroundings, and construct | assembles as an arch end. It is the schematic of the basic form of the inverted trapezoid square pillar (without chamfering) talc block.

  Embodiments of the present invention will be described below with reference to the drawings as appropriate. In order to facilitate understanding of the present application, as a premise, what is divided into block groups and connected thereto will be described, and then the block groups will be described.

(About a series of connected concrete block bodies)
In one embodiment of the present invention, FIG. 1 is an articulated concrete block body (1) for an arch bridge structure connected in series. (A) is the state which left still on the plane, (b) is the figure of the state which lifted this. The stone block (2) is a square pillar-shaped concrete block, and is composed of a symmetrical oblique side (8, 8) and a lower side (7), an upper side (6) longer than the lower side (7). The trapezoid (5) is used as a bottom surface of a quadrangular prism, and a quadrangular prism composed of side ridges (10) orthogonal to the bottom surface is used in a state of being laid down so that the inverted trapezoid can be viewed from the side. FIG. 13 shows an outline of a square pillar-shaped talc block. As for the size of this stone block, for example, the width of the upper side is 32.4 cm, the width of the lower side is 30 cm, the height is 23 cm, and the length of the side ridge (10) is 100 cm. The length of the lower side with respect to the upper side can be changed as appropriate. By changing the length, the curvature can be changed, and the arch rise and the span can be changed. However, since a large curvature change is caused by the difference in length of 1 mm, it is important to make the precision of the stab block manufacture precise.

  Now, in FIG. 1, 23 pieces of this stone block (2), geogrid (15) of connecting members embedded in the vicinity of the upper plane (9) in the extending direction of the upper side (6) of the inverted trapezoid (5) Are connected in series to form an articulated concrete block body (1) for the arch bridge structure. In the state of FIG. 1A arranged between adjacent blocks in a flatly developed state, the lower side (7) has a short length, so that a wedge-shaped gap (13) is formed. ing. In addition, although the following example demonstrates using a geogrid as an example of a connection member, it is not limited to this. The geogrid is buried at a depth of 3 cm. Then, as shown in FIG. 1 (b), when lifting so that the center becomes higher, the talc blocks naturally come into contact with each other by the suspended weight and form an arc (17) in an arch shape. It becomes. In addition, the arch stone block (2) can be constructed more stably by using an odd number of talc blocks (2) because the arch tends to be stable when the uppermost central block functions like a keystone. It becomes.

  The geogrid (15) of the connecting member is embedded in a depth of 3 cm from the upper plane (9) using a single geogrid (15) in a state where a plurality of blocks such as the talc block (2) are arranged. By doing so, it is placed so as to be in close contact with the concrete. The geogrid (15) is connected in series with the connecting surface (11) formed by being embedded in the longitudinal direction, and adjacent blocks rotate around the connecting point (12) as a connecting axis. It has become possible.

(About Geogrid)
Geogrid, which is an example of a connecting member, has a regular lattice shape made of polymer plastic resin, etc. with high tensile resistance. Used as described above. For example, a grid-like member made of a high-density polyethylene resin, such as an adem (manufactured by Maeda Kosen), which is further reinforced by appropriately arranging an aramid fiber core material therein is suitable. The lattice shape is, for example, an interval of about 5 cm in the vertical direction (longitudinal direction) × about 3 cm in the horizontal direction (width direction). It is a grid-like net as shown in FIG. 7 (a), spreads in a planar shape, and is embedded in concrete and fixed tightly. In addition to the adem, the geogrid is a trigrid (having a lattice structure in which high-strength polyester fibers are bundled as a core and polypropylene resin as a covering material), Tensor (Mitsubishi Chemical Corporation), Although a grid-like geogrid can be applied, in order to lift and connect a large number of blocks, those having particularly high tensile strength are suitable.

  Now, since the geogrid (15) of this connecting member has a core of aramid fiber disposed in a longitudinal polyethylene resin running in a direction penetrating a plurality of blocks, it has a high tensile resistance against the load caused by the connection. Can show gender. In addition, since the geogrid is formed in a lattice shape with the horizontal lines orthogonal to the vertical lines, if the grids of the vertical and horizontal lattices are appropriately synchronized with the interval between the connecting points (12), It is possible to ensure the strength at the connection location. For example, as shown in FIG. 6, by setting an integral multiple of the lattice interval as the block interval, the connection point (12) overlaps the position of the intersection where the vertical line and the horizontal line intersect at right angles. To do. Then, since the polyethylene resin of the horizontal line | wire of a grating | lattice will be located on the axis line of a connection location (12), the intensity | strength of a connection part improves. Since the block rotates in the direction of the center of gravity when the block hangs around the connection point, the strength of the geogrid increases if the interval between the grids and the axis of the connection point (12) are matched. Therefore, troubles such as stretching or cutting can be reduced, and a larger load can be endured. Then, stable connection can be secured. The overlap with the horizontal line rather than the vertical line alone increases the load capacity for suspension, and it is possible to connect more blocks to form an arch bridge with a long span and a large arch rise.

(About connected concrete block bodies that connect and integrate blocks)
Next, as another embodiment of the present invention, FIG. 2 shows an example in which a plurality of block groups (4) are connected to form a connected concrete block body (1) for an arch bridge structure. The difference from the articulated concrete block body (1) for the arch bridge structure in FIG. 1 is that it is a structure in which those divided into block groups are connected at the construction site. There is no difference in the parts other than the divided points. For example, the turnbuckle (20) is passed to the block adjacent to the lower end block (18), or the chamfered portion (14) is provided by chamfering the upper end of each block. Is the same as that described in FIG.

  Now, the block group (4) may be a combination of about 4 to 5 talc blocks (2) with geogrids embedded and combined with divided blocks. In the embodiment of the specification, what will be specifically described below with reference to FIG. 2 will be described by taking as an example a block group (4) having a structure in which divided blocks (3) are provided at the ends and used for connection as follows. As shown in FIG. 3, the block at both ends uses a divided block (3) in which the stone block (2) is equally divided vertically in the center of the inverted trapezoid, The left half block (3b) has a half-divided block (3) having a vertically divided surface (30) on the left, and the right block (3a) has a divided block (3) having a vertically divided surface (30) on the right. The left end block (3b) and the stone block (2) are connected to each other by burying the geogrid (15) in the state where about 1 to 3 blocks and the right end block (3a) are arranged in this order. Group (4). FIG. 8 shows some embedding patterns of the geogrid (15) in the block group (4).

  Then, the right end block (3a) of the block group (4) has the vertical division surface (30) of the left end block (3b) of the adjacent block group (4) at a position facing the vertical division surface (30). In this way, the steel plate (24) with the ribs (25, 25) and the eccentric washer (23) are tightened and integrally connected. Since the connected right end block (3a) and left end block (3b) are connected to each other so as to be exactly the same shape as the talc block, the arc (17) of the arch can be drawn without a sense of incongruity. , 4) can be appropriately connected.

(About fastening devices using eccentric washers)
Fixing by the eccentric washer (23) used for fastening the block group (4) and the adjacent block group (4) is to tighten the concrete blocks using the tool shown in FIG. Specifically, bolt holes are drilled in the upper planes of the right end block (3a) and the left end block (3b) to be connected, and the flat plate portion of the steel plate (24) is placed on the bolt holes. The washer is placed on the bolt hole (28, 28) provided in the plate (4) and tightened from above with the bolt (31). At that time, one of the plate holes is an elongated plate long hole (27). An eccentric washer (23) having an opening that is eccentric from the center of the disc is placed on the long hole side. At the end of the long hole side of the plate, there is an outer projection (29) in contact with the eccentric washer (23), and an inner projection in contact with the washer is also provided near the center of the plate.

  Fixing with the eccentric washer (23), after tightening the bolt lightly, by rotating the eccentric washer (23) and extruding the bolt (31) in the proximity direction so that the distance between the bolt axes is reduced, It is to adhere. The protrusion (29) on the outer side of the abutting portion that resists the pressing force generated when the eccentric washer (23) rotates, resists the tensile stress that spreads outward, and prevents the rotating eccentric washer (23). By restricting, the bolt is pressed and the concrete blocks are brought into close contact with each other. In contrast, the inner protrusion is provided so that the compressive stress is not excessively applied.

  As shown in FIG. 5, the fixing of the 1 m wide divided blocks can be stably performed by using a plurality of plates such as three plates using eccentric washers and tightening them at three positions. Further, a lower hole (34) for inserting the insert (35) is formed in the vicinity of the center of the vertically divided surface (30) of the divided block (3), and the vertically divided surfaces (30, 30) face each other to form the divided block ( When connecting 3 and 3), it is more preferable to insert an insert (35) in the interior so that the divided blocks are not easily displaced. The joint pin of the insert (35) is made of, for example, steel having a diameter of about 2 cm and a length of about 5 cm, and is inserted into an insert hole (34) drilled in the vertically divided surface. Moreover, the insert is not only difficult to be displaced during lifting, but also useful for positioning when facing each other.

(About plate ribs)
Next, the ribs (25, 25) erected on the left and right sides of the plate (24) are made of steel and form a plane perpendicular to the plane, so that they do not bend when the plane is bent. Can withstand. The connected right end block (3a) and left end block (3b) are closely coupled with the vertically divided surfaces (30, 30) facing each other. Absent. However, when a trial test was performed in which the divided block groups were connected, the load of the suspended block group (4) was applied to the connection portion. For example, the lower end block was rotated in the opposite direction, and the same was applied to the connection portion. It turns out that it happens to bend. Therefore, if the rib (25) is erected in advance so that it will not bend due to the movement of the load due to lifting, it will not bend, so the gap will open in a wedge shape at the longitudinally split surfaces (30, 30). Things can be avoided.

  On the other hand, when the block group is composed entirely of talc blocks (2), when the bolts are tightened with an eccentric washer and plate when connecting the talc blocks at both ends, ribs are not provided on the plate to be used. And This is because it is necessary to form the arc (17) so that the wedge-shaped gap (13) disappears and the blocks come into close contact with each other when being lifted from the plane and suspended. And, when connecting the stone blocks, it is desirable that the plate itself bends and bends, so it needs to be a flat plate.

(About burying connecting members in block groups)
Since the group of blocks (4) has a structure in which about 5 blocks are concatenated, as an example of a connecting member, a grid-like geogrid (15) on one side is buried in the vicinity of the upper plane so as to be in close contact with the concrete. In this case, if the block group (4) is a single unit, there is no particular difficulty in lifting and moving. FIG. 7A illustrates the geogrid (15) of the connecting member corresponding to the block group (4) from the upper plane side. As shown in FIG. 6, it is embedded several centimeters from the upper plane of the block group.

  However, when a large number of block groups (4) are connected and integrated, the blocks at both ends of the block group (4) are also subjected to the load of the block group connected downwardly hanging from the blocks. Become. Then, unlike the case of using a series of integrated geogrids (15) from end to end, the geogrid (from the concrete of the block at the end of the block group (4) has a discontinuity in the middle of the arc. 15) may fall out. Even if it is molded in close contact with concrete, when the geogrid (15) is pulled in the direction of the connecting surface (11), the contact area is small, so it cannot be held, and it will lose power and fall off. It doesn't have to happen.

  Therefore, for the sake of safety, when connecting multiple molded parts divided into block groups (4) and integrating them, especially the geogrid of the connecting members will not come off from the blocks at both ends. It is preferable to devise how to bury the end of the geogrid (15). For example, a normal geogrid is used so as to be spread out at the time of placing, and therefore is merely arranged in the vicinity of the upper plane in a plane as shown in FIG. Here, as shown in (b), (c), and (d) of FIG. 8, the method of embedding both ends of the geogrid is not a flat placement method, but the end is bent 90 degrees and the upper plane If you try to reach a deep position from the side, bend it into a U shape, round it slightly and curve it loosely in the depth direction, the geogrid in the blocks at both ends Since this is a three-dimensional positioning, when placed, the grids of the geogrid are in close contact with each other so as to be entangled in multiple directions, so that it is more difficult to fall off. Specifically, concrete should be poured over the river table of the block group at a depth of about 20 cm, and the geogrid shall be placed without any gaps. At that time, the end of the geogrid should be deeply submerged inside the concrete. Then, after embedding in a three-dimensional shape, it is preferable to place concrete to a surface layer of 3 cm and to bring the concrete into close contact with the grid of the geogrid to obtain a block group that is difficult to fall out.

(About embedding a locking pin perpendicular to the connecting surface into the connecting member and embedding it)
In the blocks at both ends of the block group (4), the geogrid of the connecting member is easy to come off. Then, it embeds in the concrete so that a pin may be driven and locked on the connection surface of a connection member from the top. Specifically, while placing the geogrid of the connecting member during placement in the formwork, using a U-shaped pin made of stainless steel, the staple needle from above is placed so as to sandwich the geogrid. In this way, the pins are driven so as to be orthogonal to the connecting surfaces, and then covered with concrete from above and buried. Since it is a pin that goes straight to the connecting surface, it can resist the force of sliding in the direction of the connecting surface, and can be prevented from coming off.
Since the pins can be used as appropriate other than the ends of the connecting members of the blocks at both ends, the adhesiveness of the concrete on the connecting surfaces can be supplemented as appropriate.

(About production of connected concrete block bodies)
There are mainly two production methods for obtaining an articulated concrete block body in which 20 or more talc blocks are continuously integrated.
(Method of connecting the basic blocks one by one by placing them in the second stage after molding)
First, each of the inverted trapezoidal square pillars that form the basic part (32) of the stone block one by one is molded with a mold, so that the inverted trapezoidal square has a height of 20 cm, an upper side of 32.4 cm, and a lower side of 30.0 cm. Obtain a concrete block of columnar basic parts. A number of these blocks are juxtaposed on the extended line of the upper side of the inverted trapezoid, and then a single geogrid is placed on top of each block. Is placed in the second stage, and a mortar is cut from above at intervals of the block, and cured to obtain integrally connected block bodies.

  Although this method can manufacture the block of the basic part (32) one by one, the mold can be made inexpensive, but the accuracy of the mold is rather high. Since 20 or more of the same shapes are connected, if the size of the basic portion (32) is not the expected shape, it will appear 20 times as many. Also, once laid, the mortar is placed again on the solid block from above, so it is not always easy to increase the adhesion strength between the mortar and the concrete sandwiching the geogrid. Depending on the condition, the mortar will float and easily peel off.

(About the method of placing in a large number of blocks with formwork)
As a method of placing a large number of blocks in a single formwork, a large number of wedge-shaped partition walls are provided at equal intervals in the short direction inside a rectangular frame that surrounds the bottom and four sides, and concrete is poured into it. In this way, a state in which a large number of blocks are arranged at a time is formed, and before the concrete poured into the depth of the apex of the wedge-shaped partition is hardened, a single geogrid is spread over the longitudinal direction on the concrete. Then, the concrete is poured and the concrete is blended into the grid of the geogrid and integrated. Geogrid is arranged at the apex of the wedge shape, and the concrete above it is divided into blocks so that it becomes a block before it hardens, or the partition wall is inserted from the upper side to the position facing the apex of the wedge shape After that, an integrated articulated concrete block body is obtained by pouring the concrete of the upper surface layer.

  According to this method, the adhesion between the geogrid and the concrete is improved, so that it is difficult for the geogrid and the concrete to fall off or peel off when lifted. However, since the size of the mold is increased and the manufacturing accuracy of the mold is required, the manufacturing difficulty of the mold is slightly increased. Moreover, since it is integrated at once with a series of integral molds, it is a large-scale work from die cutting to carrying out. In addition, every time the arch span size or arch rise height changes, it is necessary to change the size of the frame surrounding the four sides. Then, in order to give variations to the size of the arch bridge, it is not easy to prepare the formwork for each. Furthermore, precast blocks can be produced uniformly in factories, but because of their weight, it is not economical to ship to various parts of the country, so many bases are often established. Then, various large-sized formwork will be prepared for each base.

(About the manufacturing method of the block group size formwork)
Therefore, if a method of connecting block groups can be used, it becomes more practical. Since the blocks are connected in units of block groups, the size of the formwork is sufficient for the block group units. Since arching and span adjustment can be handled by the number of connections, the formwork can be shared and versatility can be achieved. Even if a large number of block groups as shown in FIG. 3 are manufactured in a factory, the weight of the block group unit is about 800 kg, so that it can be carried out by a small heavy machine and carried by a truck, and the load can be suppressed. Then, the manufacture of the block group unit is made by the following procedure when, for example, divided blocks such as vertical blocks are vertically divided at both ends.

  First, FIG. 9A shows a lower formwork (36) of a block unit, and FIG. 9B shows a state in which concrete is poured up to the depth of the apex of the wedge shape up to the basic shape. First, the four sides of a wedge-shaped (isosceles triangle) partition wall between the two opposing side walls on the long side are surrounded by four sides with a bottom surface of width 100 cm × length direction about 130 cm and a side wall of about 25 cm in height. And partitioning by arranging at an interval of 1: 2: 2: 2: 1. Since the wedge-shaped partition wall (37) has a height of 20 cm and a base of 2.4 cm, the distance between the partition walls is 30 cm between the lower ends and 32 and 4 cm between the upper ends. These molds (36) are made of steel plates, and the dimensional accuracy for each block is 1 mm or less. If the dimensional accuracy is out of order, the span will be greatly displaced, so that it is likely to be displaced when it is placed on the foundation block (39) placed on the base.

  Then, after spraying the mold release agent on the mold, the concrete is poured to a depth of 20 cm to the height of the wedge-shaped apex where the partition wall (37) of the mold (36) in FIG. Immediately before, the geogrid (15) is placed on the connecting surface (11) having a height of 20 cm over the entire surface, and is further opposed to the apex angle as a chamfered partition frame (38) from above the geogrid (15). By placing a partition with an inverted isosceles triangle with a vertical angle facing down at the position, and pouring the concrete further, the concrete is distributed in the grid of the geogrid (15), and the geogrid (15) is placed inside the concrete block. It is buried and fixed so that it is firmly attached to. After the placement, the concrete formwork is cured for several days to a week in a humid environment, and then removed from the formwork to obtain the block group (4) in FIG.

  In addition, when the mold is manufactured in the unit of the block group (4), as described above, as shown in FIGS. 8B to 8D, the position of the apex of the partition wall which is the connecting surface is defined as the geogrid. When placing at a depth of 3 cm, if the end (16) of the geogrid (15) is driven deeper into the blocks at both ends, the geogrid (15) is divided into blocks (3 ) Is difficult to remove. The end (16) of the geogrid is bent 90 degrees downward, folded back further into a U-shape, or bent downward and bent loosely. ) So as to dive deeper than the connecting surface (11). Further, a reinforcing pin or the like may be embedded in the bent end of the geogrid to further strengthen the pull-out. The end (16) is submerged so as not to include air when placing, and is sufficiently adhered to the concrete.

  When changing the arch rise (43) or the span (42), it is possible to change the number of connected talc blocks or blocks, but to adjust more flexibly, this wedge-shaped partition wedge shape You may manufacture so that the inclination of the slope of the adjacent surface with an adjacent block may be changed directly by changing the length between the lower ends of the partition walls. By combining both, flexible size adjustment becomes possible. Increasing the apex angle of the isosceles triangle cross section of the wedge-shaped partition wall (37) and increasing the base length will increase the slope of the hypotenuse, so increase the curvature of the arc of the arch when it is lifted This increases the arch rise while narrowing the arch span. And if multiple types of formwork parts of partition walls (37) with different apex angles (base lengths) of isosceles triangles are prepared, the design and manufacture of arch bridges with different arch spans and arch rises can be made flexible. In addition, when a variation of the part of the formwork with a size of about 1 meter x 1.3 meters is provided, it does not take up much space and can be flexible while being compact. For example, the bottom of the partition wall is 20 mm, 22 mm, 24 mm, 26 mm, 28 mm, and 30 mm. When the bottom of the partition wall is shorter, the arc of the arc formed when lifting is looser, the span is longer, and the arch rise is higher. When the bottom of the partition wall is long, the curvature of the arc increases and the arch rise increases, while the span decreases.

  As a specific example, FIG. 11 shows a state of an arc when the length of the lower side of the talc block is changed by 4 mm, with (a) and (b) superimposed. The (a) and (b) talc blocks are only 4mm longer on the lower side than (b), and there is no significant difference except that the slope of the inverted trapezoidal hypotenuse is gentler on (a). . First, when the stone block (a) has a height of 23 cm, a depth of 3 cm from the upper plane is the connecting surface of the geogrid, the width of the connecting portion is 32.4 cm, and the lower side is 30 cm (that is, the formwork) When the base of the partition wall is 24 mm, the span (42) between the two end blocks of the arch composed of 21 talc blocks (a) is 4.67 m, and the arch rise (43) is 1.73 m. Next, when the bottom side of the talc block (b) is reduced by 4 mm to 29.6 cm (that is, the bottom side of the partition wall of the formwork is set to 28 mm), the arch of the talc block (b) consisting of 21 blocks The span (42) between the both end blocks is 4.22 m, and the arch rise (43) is 1.90 m. While the arch height was 17 cm higher, the 45 cm span was smaller.

  Next, the case where the number of connected stone blocks is 23 is as follows. Scorpion block (a) 23 spans (42) is 4.92m, arch rise (43) is 2.02m, 23 span blocks (b) 23 spans (42) is 4.24m, arch rise (43 ) Is 2.19 m. In (b), the arch height was 17 cm higher than (a), while the span was 68 cm smaller.

  Since the curvature of the arch is different between (a) and (b), variations in the arch can be easily increased by changing the shape of the talc block. In addition, since the number of talc blocks can be adjusted by cutting the geogrid at the connection location (12), the number of blocks can be adjusted relatively easily.

  In addition, since the arc of the arch (17) is greatly changed in this way only by the difference in the length of the lower side of the talc block by 4 mm, the dimensional accuracy of the talc block is required to be strict. When manufacturing with a mold for each block group, the accuracy of the partition wall (37) can be increased to about 0.1 to 0.2 mm, and the error can be leveled by the four partition walls. Variations can be made inconspicuous.

  In order to sufficiently extract the strength of the concrete, after curing for several days to a week in a state of high humidity control, the upper and lower and side wall molds are removed, and the block group shown in FIG. 3 is taken out. On the upper plane of the central block of the block group, two hooking hooks are provided on the upper plane of the central block as a hanging part (33) for hanging the ball. Specifically, a round protrusion is left at the center, and a groove is dug so that the wire passes to a depth of about 3 cm. In order to give strength for slinging, if necessary, reinforcement may be provided by appropriately arranging the bars.

(About the point where the lower end block opens like a wedge)
Now, FIG.1 (b) illustrates the state of the connecting concrete block body (1) for the arch bridge structure which hangs by drawing the arc (17) of the arch by being lifted so that the center becomes high. Yes. However, of the suspended talc block (2), the lower end block (18) is rotated by its own weight so that the center of gravity (19) is directly below the connection point (12). ) And hung in a wedge-like open state without being lined up along the line. If it is simply suspended as described above, it will be suspended in an open state, and it will not be possible to place the important lower end block (18) on the base block as a base at an appropriate position. Therefore, it becomes necessary to correct the position to an appropriate position.

  Of course, when the tilt angle of the block is shallow, it moves in the direction along the arc of the arch due to the movement of the center of gravity, so that the wedge-shaped gap with the adjacent block is filled just by suspending, so along the appropriate arc (17) An arch is formed. Therefore, if it is a bridge with a small span or a small arch rise, it can be suspended without any support, and it can be suspended without any measures. There are times when it can be installed. Therefore, the phenomenon that the lower end block (18) opens is not necessarily encountered. However, when the span of the arch is large or the arch rise is high, if the inclination of the upper plane of the block in the vicinity of the lower end is large, the center of gravity is directed directly below the connection point with the connection point (12) as the axis. From the viewpoint of rotation, if the arc (17) of the arch is moved to a position where the arch arc (17) is appropriately drawn so as to be in contact with the adjacent block, the center of gravity (19) is positioned closer to the center of the arc than the connected portion. Thus, it has been found that the gap is opened in a wedge shape so as to be rotated by the suspension load so as to be separated from the position of the arc.

  If the number of connected stone blocks (2) is large, the suspended load will be a large load on the connection point (12) of the geogrid (15), so many connections are not easy in the first place. If the arch rise becomes longer and the arch rise becomes higher, the inclination of the upper plane (9) becomes stronger, so that the direction of rotation of the block by the center of gravity (19) becomes an unexpected reverse direction and tends to open in a wedge shape. Become. Therefore, in order to lengthen the span, the following device is required again.

(About restraining members)
First, a constraining member such as a turnbuckle (20) is installed between a block near the left and right ends, including the lower end block (18), and a block adjacent thereto. The restraining member is not limited to a turnbuckle, and a wire, a rubber string, or a length adjustment by a buckle can be applied. The turnbuckle can be applied safely and reliably as follows. Now, the turnbuckle (20) is an instrument having a turnbuckle body (21) at the center and turnbuckle bolts (22, 22) with opposite screw directions on the left and right sides of the turnbuckle (20) below or on the side of the block. It is assumed that the degree of opening of the wedge-shaped gap (13) can be adjusted by rotating the turnbuckle body (21) in connection with the lower part. By the way, in a state where the talc block (2) is connected and juxtaposed on a plane, the upper side is 324 mm, the lower side is 300 mm, and the connecting surface (11) in which the geogrid (15) is embedded has a thickness of 230 mm. The depth is 30 mm from the upper plane (9). Therefore, the wedge-shaped gap (13) formed between adjacent talc blocks (2) is an isosceles triangle having a width of 24 mm and a height of 20 mm when placed on a flat surface, and the opening angle of the wedge Is about 17 degrees.

  By restricting the opening and closing of adjacent blocks so that the wedge-shaped gap (13) does not widen by the turnbuckle (20), the turnbuckle body (21) is rotated to narrow the opening gradually, Gradually the opening of both blocks is canceled and the lower arc block (18) is finally guided to the position of the lower block at the position of the arc (17) of the arch, and finally the arc ( 17) Place the entire connected concrete block body (1) for the arch bridge structure depicting 17).

  The restraining member may be a stretchable member such as rubber, but it is powerful to apply tension in a state of being separated and force the rubber around, and if tension occurs on a plane, the blocks will shrink. There is also a possibility of missing by tilting. Therefore, it can be said that the turnbuckle (20) is easier to handle because there is no behavior such as contraction.

(About chamfering)
Next, the upper corner of the inverted trapezoid (5) of the square pillar talc block is chamfered at the upper part from the connecting surface (11) by the connecting member formed at a depth of 3 cm from the upper plane (9). The chamfered portion (14) is formed. The notch of the chamfered portion (14) has a size of 3 cm in depth and 1 cm in width in this embodiment. The angle is a little less than 20 degrees. Although the chamfered portion (14) is illustrated linearly, the chamfered portion may be rounded in a circular arc shape.

  As described above, when the lower end block (18) is rotated so as to open in the direction opposite to the arc of the arch (17) due to the movement of the center of gravity, in some cases, the lower side block (18) may be on the opposite side. It can happen to open. Then, since the upper plane originally has a connection point (12) at a depth of 3 cm, the corner above the connection point (12) easily comes into contact with that of the adjacent block. In the middle of lifting the block, the block near the ground surface may be curved in the opposite direction to the curve of the arc (17) of the arch and draw an S-shape. Then, since this portion also bends and opens in the opposite direction, the opening of the wedge-shaped gap becomes larger than when it is on a plane, and the upper end portion is lost. These may lead to defects, delamination and cracks in addition to the end of the upper plane.

  However, if the chamfered portion (14) is provided in advance, an inclination of about 19 degrees is given by chamfering with the above size. Even if the chamfered portion is opened in the opposite direction by a total of 38 degrees on the left and right, there is a margin that the chamfered portion does not contact. Therefore, the upper ends of adjacent blocks are less likely to come into contact with each other. The chamfering provides a sufficient margin even when the wedge-shaped opening is greatly reversed when it becomes S-shaped when it is lifted.

(About installation of arch bridge)
FIG. 12 shows one of installation procedures for constructing an arch bridge in which a horizontal upper path is formed above an articulated concrete block body (1) formed with an arc by installing the block of the present invention. Since the concrete blocks of the arch bridge do not move due to friction when the stones come into close contact with each other, compressive stress is transmitted to both ends as they are. As a result, lateral pressure (thrust) is generated which tends to spread obliquely downward toward the outer direction, and it is important to resist this with a foundation block or the like. The articulated concrete block body of the present invention is suspended and placed on a foundation such as a foundation block, and the upper part is filled with heavy concrete or the like to form a horizontal upper road (44) as an upper arch bridge. It can be used. The installation procedure of the upper arch bridge using the present invention is as follows as an example.

-In step (a), a precast concrete (4) block group or a series of connected concrete block bodies (1) obtained by molding in a formwork is transported to the site, and the connected concrete is integrated in the field. This is the step of making the block body (1).
-A process (b) is a basic block (39) which receives the compression load of the block lifted in the arch shape. Similarly, it is a process of producing precast concrete with a mold and transporting it to the site. The foundation block (39) may be of a size that can form a wide bridge by arranging a plurality of connected concrete block bodies (1) in parallel, such as a length of 4 m.
-In step (c), first, a basic block is horizontally installed with a predetermined span. Under the foundation block, a foundation is horizontally formed, and gravel and crushed stone are laid as appropriate. Mortar is laid, and the foundation block (39) is placed thereon.
-Step (d) The connected concrete block bodies (1) are slung in three places, the center wire is made shorter, and it is gradually lifted with a crane.
Step (e) The connected concrete block body (1) that is lifted and formed into an arch shape is placed on the foundation block (39). When the arc (17) is not drawn by the lower end block (18), it is restrained by using a turnbuckle (20) as appropriate, and is placed in close contact with the adjacent block before being placed on the foundation block (39).

Step (f) Next to the connected concrete block body (1) placed in an arch shape, the connected concrete block body (1) is further placed side by side.
Step (g) Place a plurality of rows of arch-shaped connected concrete block bodies (1) on the foundation block (39), and fasten each other with an eccentric washer or the like.
-Process (h) A formwork for placing concrete around the arch block is installed.
-Process (i) The concrete used as a backfill (40) is poured into a formwork, and the lower part of a foundation block and an arch is fixed.
-Process (j) The height of a backfill (40) is gradually made high by repeating a formwork and concrete placement.
-Process (k) Concrete is cast to the height which can run horizontally in the connecting concrete block body of an arch, and a horizontal upper road (44) is formed, and it is set as an upper arch bridge.

  When extending the width of the bridge by laying a plurality of rows of arches, the work may be advanced while appropriately connecting with a fastener or the like using an eccentric washer. In addition, for the steps (j) to (k), the size is such that the precast concrete block of the outer wall panel block (41) that can make up the exterior of the bridge covers the arc of the arch and the height of the upper horizontal passage. It is also possible to form an upper arch bridge having an upper path (44) by connecting and fixing the panel to the facing panel in the bridge width direction and then placing the interior with concrete. If the decorative panel is used, it is easy to reproduce the masonry pattern on the outer surface as if it were a stone arch bridge as a whole, and the texture can be made richer.

  The strength of the arch bridge, including the placement of surrounding backfill, can be simulated by a computer by FEM analysis using the finite element method, etc., so that sufficient safety is ensured even by the means of the present invention. It has been confirmed that it can be done. The arch arc, backfill, and foundation block can all be used in consideration of safety because they can withstand loads that occur during normal use and withstand shear stresses during earthquakes, etc. be able to.

DESCRIPTION OF SYMBOLS 1 Articulated concrete block body for arch bridge structure 2 Stone block 3 Divided block 3a Right end block 3b Left end block 4 Block group 5 Reverse trapezoid 6 Upper side 7 Lower side 8 Slope side 9 Upper plane 10 Side edge 11 Connection surface 12 Connection location 13 Wedge shape Gap 14 Chamfer 15 Geogrid 16 End 17 Arc 18 Bottom Block 19 Center of Gravity 20 Turn Buckle 21 Turn Buckle Body 22 Turn Buckle Bolt 23 Eccentric Washer 24 Plate 25 Rib 26 Bolt Hole 27 Plate Long Hole 28 Plate Hole 29 Projection 30 Vertical Split surface 31 Bolt 32 Basic part 33 Hanging part 34 Insert hole 35 Insert 36 Mold frame 37 Partition wall 38 Chamfered part partition frame 39 Base block 40 Backfill 41 Cosmetic panel block 42 Span 43 Archize 44 Top Road

Claims (8)

  A square columnar talc block with an inverted trapezoid that is parallel to the left and right hypotenuses, the lower side, and the lower side and that is longer than the lower side and whose side edges are orthogonal to the bottom, Arrange the multiple side-by-side arrangement in the extension direction of the upper side of the inverted trapezoid with the side surface as the lower plane and the side surface in contact with the upper side as the upper plane, so that the connecting member is embedded inside the vicinity of the upper plane The block group in a state where the mortar block suspended downward from the adjacent mortar block and the connection point as an axis is connected in a rotatable manner to form a series of blocks, and the whole An articulated concrete block for an arch bridge structure that can be formed into an arc shape with the lower side as the inner periphery and the upper side as the outer periphery when it is lifted.   An inverted trapezoidal block with a left and right hypotenuse and an upper trapezoid parallel to the lower side and the upper side that is longer than the lower side is used as the bottom, and a square columnar talc block with side ridges orthogonal to this is formed. Of half-size blocks that are divided in half from top to bottom, those whose vertical planes are on the right are right-end blocks, and those whose vertical planes are on the left are left-end blocks 1 to 4 sarcolithic blocks are arranged between the left end block and the right end block, and a connecting member is buried in the vicinity of the upper plane of each block, and the adjacent talc block and the connecting location are located. A block group in a state where the talc blocks suspended downward as a shaft are connected in a pivotable manner, and a block group of a plurality of groups is formed such that one side of the adjacent block group and the vertically divided surface face each other. A series integrally by was sintered, and the inner peripheral of the lower side when lifting the whole was possible to form an arc shape to the outer peripheral of the upper side, articulated concrete block member for arch bridge structure.   To connect the left end block and the right end block with the vertically divided surfaces facing each other, a left bolt hole opened in the upper plane of the left end block and a right bolt hole opened in the upper plane of the right end block opposite to the left bolt block. A metal plate with a U-shaped cross section provided at both ends is placed and placed between them. One of the pilot holes corresponding to the left and right bolt holes penetrated through the plate is a round hole and the other is a long hole. Yes, the long hole is a long hole that opens from the position corresponding to the bolt hole toward the round hole side, and the disc-shaped washer set on the plate of this long hole is at a position eccentric from the center of the disk. It is an eccentric washer with an insertion hole open, and the outer diameter of the disk of the eccentric washer is provided with a counter plate that gives a pressing force when rotating the eccentric washer that abuts on the plate. 3. Arch according to claim 2, characterized in that Articulated concrete block body for the structure.   In the connection of the blocks in the block group by the connection member, the connection members arranged in the longitudinal direction on the connection surface parallel to the upper plane are deeper than the connection surface in the block at both ends of the block group. The articulated concrete block body for an arch bridge structure according to any one of claims 1 to 3, wherein the concrete block body is embedded.   In connecting the blocks in the block group by the connecting member, a locking pin orthogonal to the connecting surface is arranged on the connecting member arranged in the longitudinal direction on the connecting surface parallel to the upper plane. The connected concrete block body for the arch bridge structure according to any one of claims 1 to 4.   The restraint member which can adjust the opening degree of the wedge-shaped clearance gap formed between both blocks of the talc block or the end block and the talc block adjacent thereto is provided. The connected concrete block body for arch bridge structures in any one of claim | item 5.   The connected concrete block body for an arch bridge structure according to any one of claims 1 to 6, wherein a corner portion of the upper side of the block is chamfered upward from the connection location.   An upper arch comprising an arc-shaped arch formed of the connecting concrete block body for the arch bridge structure according to any one of claims 1 to 7, and a horizontal upper path disposed above the arch. bridge.