JP5587489B1 - Wavebreak block, wavebreak block structure, and construction method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wavebreak block, a wavebreak block structure, and a method for constructing a wavebreak block structure capable of reliably reducing, quenching, and breaking a wave force in a coastal area.
A wavebreak block invented this time has a wavebreak function similar to that of a caisson by combining a wavebreak connection block, a wavebreak plate and a wavebreak chamber. It has a wave-dissipating function similar to that of the seawater breakwater, and also has a fish reef function as an underwater cave, and has stability similar to that of caisson against rough waves from the open sea. In this structure, the wave-dissipating blocks that make up each wave-blocking block are arranged in a staggered pattern in the top-bottom, left-right, and right-and-left directions, and the uneven parts of each wave-blocking block can be firmly fitted together in the vertical direction. None, it is possible to build up a number of wave blocking layers.
[Selection] Figure 1

Description

  [Technical Field] The present invention relates to a wave-dissipating connection block, a wave-breaking block, a wave-dissipating block structure, a wave-blocking block structure, a wave-dissipating block structure, and a wave-breaking block that reduce, wave-break and wave-break waves in the coast. The present invention relates to a structure construction method.

  Conventionally, there are wave extinction and wave breaking as methods for reducing the wave power of waves in the coastal area. The wave extinction is to reduce the energy of the wave by reducing the scale of the wave rotation motion while leaving the wave shape by the wave rotation motion in the vertical direction in the wave traveling direction. Breaking waves in the coastal area means that the vertical movement of waves in the direction of wave travel is inhibited by frictional and vertical rotation movements by the bottom of the inclined wall, horizontal wall, vertical wall, reef, or structure. This breaks the rotational motion in the vertical direction and converts it into a stepped intermittent flow. The wave-blocking block and the wave-dissipating connection block of the present invention eliminates all the vertical walls of a large building building, and prevents a structure such as a large building building composed of floors, ceilings, and pillars from Disassembled into blocks or wave-dissipating connection blocks or wave-dissipating blocks and stacking wave-breaking blocks or wave-dissipating connection blocks or wave-dissipating blocks on the site to create a mass such as a breakwater or wave breaker, such as a long and thin rectangular building Assume that a concrete structure is assembled.

  In general, for a breakwater in which only transmission-type deformed wave-dissipating blocks are accumulated, a method for reducing the wave force by wave-dissipation is used. A breakwater with a deformed wave breaker block is a complex gap space formed in the structure, and the energy of the wave is dispersed by a complicated solid maze to reduce the energy. The energy deactivation rate is generally said to be up to about 30%, but the wave energy acting on this deformed wave-dissipating block is compared to the wave energy acting on an impervious wall structure such as caisson. It's not that big.

  Breaking waves are a fast intermittent flow that revolves the rotational energy of waves to a stepped wave of the river flow (horizontal reciprocating water flow, the flow from the open sea side acts by the large force of the fast flow, but the return flow is the open sea It works with a much smaller force than the flow from the side.) A breakwater made of a non-permeable wall structure such as a caisson breaks the waves and at the same time greatly changes the direction of the flow to be perpendicular to the direction of the wall so that much of the wave energy is lost. Therefore, a large wave force acts on the breakwater which is a wall structure.

  For example, the environmental improvement block disclosed in Patent Document 1 is a block in which a main body is integrally formed of concrete, a culture part holding a shell is formed in the main body, and a leg is provided on the main body. When placed on a place, the culture part is not in close contact with the placement target surface by the legs, and the outer shape of the main body part is formed so that the outside communicates with the culture part.

JP 2004-324414 A

  Currently, breakwaters such as offshore dikes, submerged dikes, artificial reefs, and jetty used to prevent coastal erosion generally have a structure in which irregular shaped wavebreak blocks with complex shapes are piled up randomly. The gap space between the deformed wave-dissipating blocks is configured in a complex manner like a three-dimensional maze, and the energy of the waves is dispersed and reduced by the complicated three-dimensional maze. Generally, the porosity is approximately 50 to 60. %. Since the irregular wave-dissipating block is made of ordinary concrete, the specific gravity is about 2.2 to 2.3, and generally the weight of one block is not so large. Intermeshing between them becomes weak. For this reason, irregular shaped wave blocks piled up in random stacks will be swept away and moved by waves when hit by a large wave, and the height of the wave breakwater will be lowered, so it is often deformed There was a problem that additional stacking repair of the wave-dissipating block was necessary.

  The breakwater caisson, which is a wall structure, is a structure in which large rectangular parallelepiped reinforced concrete arks are stacked and there is no meshing between the upper, lower, left, and right caisson and caisson, and the rough sea waves from the open sea On the other hand, because it forms a wall structure, it sometimes moves due to a large impact force of a large wave, or the wave splash rises on the wall surface on the open sea side, and the splash splashes into the port, causing the inside of the port to ripple again Will do. For this reason, in order to reduce the movement of caisson and the amount of wave overtopping from the breakwater, adjacent to the outer sea side of the caisson, the transmission-type deformed wave-dissipating blocks are piled up in a random product to reduce the energy of the waves. In order to reduce the impact force of a large wave acting on the surface as much as possible, a construction method using caisson and deformed wave-dissipating block stacking is generally performed. At this time, since the deformed wave-dissipating blocks are stacked in a gradually divergent shape as it goes down, a larger number of deformed wave-dissipating blocks are required as the water depth increases. The accumulated gradient of irregular wave-dissipating blocks to be stacked is generally 1: 1.3 to 1: 1.5, but the stability of the irregular wave-dissipating blocks that are accumulated is improved as the accumulation gradient is gentler. The steep slope makes the stability worse. The deformed wave-dissipating block that is stacked up has a lower depth with respect to the waves in the upper layer closer to the water surface, and the wave-dissipating effect on the waves is reduced. The rotational motion of waves is mainly near the water surface, and the scale of the rotational motion rapidly decreases as the water depth increases. The deformed wave-dissipating block is a deformed wave-dissipating block that is installed in a deep part of the water. The deformed wave-dissipating block mainly supports the deformed wave-dissipating block that is installed near the water surface, and hardly participates in the wave-dissipating action. Also, in this construction method, the waves broken by the wall of the caisson go up into the air, so that the falling water and the lower component of the broken waves are combined, and the gap space of the piled deformed wave block Will flow downward along the wall of the caisson and will change the direction of the flow in the direction of the open sea near the seabed. This flow flows as a submerged flow toward the open sea in the lower part of the stacked irregular wave block body, moves the abnormal wave block stacked on the front of the caisson in the open sea direction, and sinks the pile height. There was a problem that it was often necessary to repair and build up the irregular wave-dissipating blocks.

  Furthermore, the construction method that uses a combination of non-transparent caisson and transmissive deformed wave block increases the construction cost. Several "type" breakwaters have been devised. This “upright wave breaking block” type breakwater is used in “a combination of caisson and upright wave breaking block” or “upright wave breaking block alone”. However, the "upright wave breaker blocks" that are currently being devised are both less stable and the wave breaker moves and jumps due to the impact of large waves. There was a problem that it could not be used in places where rough waves hit directly.

  The breakwater of the port is required to calm the waves so that people can get on and off the ship moored on the quay in the port and unload cargo. For this reason, the wave height transmission rate from the open sea to the harbor is determined by the intrusion wave from the opening between the breakwaters for ships to enter and exit the harbor, the transmitted wave from the breakwater, and the overtopping wave transmitted over the breakwater. In addition, the wave height transmission rate from the open sea to the port, including the transmitted waves from the basic mound, is generally set to be about 0.2 to 0.25 for the waves to be designed from the open sea. It is normal. The waves in the port that would impede the quietness of the port are the intrusion waves from the opening between the breakwaters for ships to enter and leave the port, and if the breakwater is impervious, most of the overtopping transmission waves from the breakwaters Is the cause. On the other hand, when the breakwater is built only with a transmission block, the higher the transmission of the transmission breakwater, the higher the top of the breakwater and the smaller the amount of overtopping transmission. It becomes. In addition, the overtopping transmission wave is generated only when the wave height is large. However, in the transmission type breakwater built only with the transmission type block, the transmission wave is generated even at a small wave height that does not cause overtopping. The type breakwater has a problem that the quietness of the harbor at normal times may be deteriorated.

  The breakwater with caisson structure is difficult to raise the breakwater after construction, even if it has a large amount of wave overtopping from the breakwater due to a wave that is larger than expected, and disturbs the tranquility of the harbor. In addition, when caisson moves or falls due to a large wave, the weight of the caisson is thousands of tons and it is very large and heavy, so it is very difficult to lift those caissons and restore them to their original location, It will be necessary to destroy and remove the damaged caisson and recreate it. In addition, impervious breakwaters such as caisson block the exchange of seawater between the harbor and the open sea, deteriorate the water quality in the harbor, and hinder the traffic of fish between the open sea and the harbor. In addition, there was a problem that the fish reef effect such as underwater cave as an evacuation site and rest area could not be secured.

  Since the environment improvement block disclosed in Patent Document 1 is used in combination with the existing upright wave-dissipating block, the stability is low, and the upright wave-dissipating block is moved or jumped by the impact force of a large wave. There is a problem that it cannot be used in places where the rough seas of the open sea, such as the Pacific Ocean and the Sea of Japan, attack directly.

  From these facts, as a wave-blocking block, the caisson and the causal of the irregular wave-dissipating block are generally used on the outer sea side of the caisson, but it has the same wave-breaking function as the caisson. In addition, it has a wave-dissipating function similar to the wave-dissipating action due to the accumulation of irregular-shaped wave-dissipating blocks, and also has a fish reef function as an underwater cave, and stability similar to caisson against rough waves from the open sea It is desired to develop a breakwater block having The wave breaker blocks that have been conceived this time satisfy these requirements, and each wave breaker block is stacked in a zigzag pattern so that the wave breaker blocks that make up each wave break block are arranged in a zigzag pattern on the top and bottom. A structure in which the blocks can be firmly fitted in the vertical direction is formed, and a number of layers of wave blocking blocks can be stacked, and a solid mass concrete structure of wave blocking blocks and a construction method thereof have been newly devised. Therefore, the present invention has been devised in view of the above-described problems, and the object of the present invention is to provide a wave protection capable of surely reducing, quenching and breaking the wave power of the waves in the coastal area. An object of the present invention is to provide a block and a wave-blocking block structure and a construction method thereof.

  The wave-dissipating connection block 11 according to the first aspect of the invention is a wave-dissipating connection block 11 that reduces the wave power of the waves in the coastal region, and the land-side room 2 provided on the land side and the sea side of the land-side room 2 The land side chamber 2 and the sea side chamber 6 are formed by connecting the land side chamber 2 and the sea side chamber 6 into a straight, substantially rectangular parallelepiped shape. The side chamber 2 and the sea side chamber 6 are configured by connecting the side surfaces of substantially the same shape and the same size of the wave-dissipating blocks 10 having substantially the same rectangular parallelepiped shape in a straight line. The height of the land-side room 2 and the sea-side room 6 of the wave-dissipating connection block 11 is substantially the same as the height of each of the wave-dissipating blocks 10. Each wave-dissipating block 10 has substantially the same width, and the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f The wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are connected to each other, and each wave-dissipating block upper plate 10e constituting the upper plate of the land-side chamber 2 and the sea-side chamber 6 has a side surface. Is formed in a substantially vertical plane, the planar shape is formed in a substantially rectangular shape, and the upper plate convex portion 10j having a substantially quadrangular pyramid shape protruding upward at the four corners of the upper surface, and the substantially central portion of the upper surface The upper plate recess 10m having a substantially inverted quadrangular pyramid shape that is recessed downward is formed, and each wave-dissipating block lower plate 10f constituting the lower plate of the land side chamber 2 and the sea side chamber 6 is a plane whose side is substantially vertical. The lower plate convex portion 10k having a substantially inverted quadrangular truncated pyramid shape that protrudes downward at the four corners of the lower surface and the upper portion at the substantially central portion of the lower surface is formed upward. An indented block upper plate 10e is formed with a lower plate recess 10n having a substantially quadrangular truncated pyramid shape. The wave-dissipating block lower plate 10f is substantially symmetrical with the same thickness, and the upper and lower surfaces of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are substantially parallel to each other and have a planar shape. The upper surface of the wave-dissipating block upper plate 10e and the lower surface of the wave-dissipating block lower plate 10f are formed on the upper surface of the upper plate convex portion 10j and the lower surface of the upper plate concave portion 10m, respectively. The upper plate projections 10j and the lower plate projections of the wave-dissipating block 10 are formed substantially parallel and substantially horizontal to the lower surface of the lower plate projection 10k and the upper surface of the lower plate recess 10n of the wave-dissipating block lower plate 10f. The portions 10k are substantially the same shape and the same size, and the planar shape is substantially similar to the planar shape of the wave-dissipating block 10, and the upper plate concave portion 10m and the lower plate concave portion 10n of the wave-dissipating block 10 are substantially identical and identical to each other. Dimension, flat shape is wave-dissipating block The side surface of the wave-dissipating block upper plate 10e and the side surface of the wave-dissipating block lower plate 10f form a common substantially vertical plane that faces the same direction, and the wave-dissipating block upper plate 10e. The upper and lower sides of the flat surface of the upper surface of the wave-dissipating block and the lower surface of the wave-dissipating block lower plate 10f, the upper plate convex portions 10j and the upper plate concave portions 10m and the wave-dissipating block lower plate 10f of the upper surface of the wave-dissipating block upper plate 10e. The short side and the long side of each planar shape of the lower plate convex portion 10k and the lower plate concave portion 10n on the lower surface form a substantially parallel line in which the short sides and the long sides are directed in the same direction. The two outer side surfaces of the upper plate convex portion 10j of the wave block 10 are respectively two side surfaces of the wave-dissipating block upper plate 10e sandwiching the corner having the upper plate convex portion 10j of the wave-dissipating block upper plate 10e. Two nearly vertical flats extending from And each of the two outer surfaces of the lower plate convex portion 10k of the wave-dissipating block 10 has the lower plate convex portion 10k of the wave-dissipating block lower plate 10f. The wave-dissipating block lower plate 10f sandwiching the corner portion includes two substantially vertical planes extending from two side surfaces and the same substantially vertical plane respectively facing the same direction, and a plurality of the wave-dissipating blocks 10 are provided. The connecting pillar 10g is formed by joining the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f at the four corners and substantially the central part of each wave-dissipating block 10 to thereby form each wave-dissipating block 10 in a substantially rectangular parallelepiped outline. The upper plate concave portion 10m and the lower plate convex portion 10k of the wave-dissipating block 10 are such that the four wave-dissipating blocks 10 having substantially the same shape and the same size are substantially in contact with each other. The four wave-dissipating blocks The outer edges of the 10 planar shapes are assembled so as to be substantially similar to the planar shape of the wave-dissipating block 10, and four pieces each including one each of the lower plate projections 10 k of each wave-dissipating block 10 are arranged at the center. The planar outer edge in which the lower plate convex portions 10k are assembled is substantially similar to the planar shape of the wave-dissipating block 10, and the large lower plate convex portion is adjacent to the upper plate concave portion 10m of the lower wave-dissipating block 10 adjacent thereto. The lower plate concave portion 10n and the upper plate convex portion 10j of the wave-dissipating block 10 are formed so as to be fitted to each other, and the four wave-dissipating blocks 10 having substantially the same type and the same size are substantially in contact with each other. In this way, the four outer edges of the wave-dissipating blocks 10 are assembled such that the planar outer edges thereof are substantially similar to the planar shape of the wave-dissipating blocks 10, and the upper plate convex portion of each wave-dissipating block 10 is centered. A set of four upper plate protrusions 10j each consisting of one of each 10j The planar outer edge formed is substantially similar to the planar shape of the wave-dissipating block 10, and is formed so that this large upper plate convex portion can be fitted into the lower plate concave portion 10 n of the adjacent upper wave-dissipating block 10. It is characterized by that.

A wavebreak block 1 according to a second invention is a wavebreak block 1 that reduces, suppresses, and breaks the wave power of a wave in a coastal area, and includes a land-side chamber 2 provided on the land side, and a land-side chamber 2 The seaside room 4 provided on the sea side and the seaside room 6 provided on the sea side of the wavebreak room 4 are provided. The land side room 2, the wavebreak room 4, and the sea side room 6 are the land side room 2 and the seaside room. The wave chamber 4 and the sea-side chamber 6 are connected to form a straight, substantially rectangular parallelepiped shape, and the land-side chamber 2 and the sea-side chamber 6 constituting the wave-blocking block 1 are approximately rectangular parallelepiped-shaped, approximately the same shape and several dimensions. The wave-dissipating block 11 has a substantially rectangular parallelepiped shape, and the wave-dissipating block 10 at the end of the wave-disconnecting block 11 is a wave-blocking block. 1 cut in half at the substantially center of the wave-dissipating block 10 on a substantially vertical plane in a direction substantially perpendicular to the central axis in the major axis direction of 1 The remaining half wave-dissipating block 10a connected to the wave-dissipating connecting block 11 is removed, and the height of the wave-dissipating block 10 is equal to the height of the land-side chamber 2 and the sea-side chamber 6 of the wave-blocking block 1. The width of the wave-dissipating block 10 is substantially the same as the width of the land-side room 2 and the sea-side room 6 of the wave-blocking block 1, and the land-side room 2 and the sea-side room 6 constituting the wave-blocking block 1 are The wave-dissipating block 10 at one end of the wave-dissipating connecting block 11 is half of the wave-dissipating block 10 at the approximate center of the wave-dissipating block 10 at a substantially vertical plane perpendicular to the central axis in the major axis direction of the wave-blocking block 1. The wave-removing edge connecting block 12 is the remaining part of the wave-removing connecting block 11 from which the cut pieces are removed. Each wave-dissipating block 10 includes a wave-dissipating block upper plate 10e and a wave-dissipating block. Block lower plate 10f, wave-dissipating block upper plate 10e, and wave-dissipating block bottom Each wave-dissipating block upper plate 10e having a plurality of connecting pillars 10g for connecting to 10f and constituting the upper plate of the land-side chamber 2 and the sea-side chamber 6 is formed into a plane shape with side surfaces formed in a substantially vertical plane. Is formed in a substantially rectangular shape, and has a substantially quadrangular pyramid-shaped upper plate convex portion 10j that protrudes upward at the four corners of the upper surface, and a substantially inverted square pyramid that is recessed downward at the substantially central portion of the upper surface. A trapezoidal upper plate recess 10m is formed, and each wave-dissipating block lower plate 10f constituting the lower plate of the land side chamber 2 and the sea side chamber 6 has a side surface formed in a substantially vertical plane, and the plane shape is substantially rectangular. And a lower plate convex portion 10k having a substantially inverted quadrangular frustum shape that protrudes downward at the four corners of the lower surface, and a substantially square frustum shape that is recessed upward at a substantially central portion of the lower surface. The lower plate recess 10n is formed, and the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are substantially mutually separated. The upper and lower surfaces of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are substantially parallel to each other and are substantially parallel to each other and have a planar shape that is substantially the same shape and size. The upper surface of the upper plate 10e and the lower surface of the wave-dissipating block lower plate 10f are the upper surface of the upper plate convex portion 10j of the wave-dissipating block upper plate 10e and the lower surface of the upper plate concave portion 10m, and the lower plate convex portion of the wave-dissipating block lower plate 10f. The upper plate convex portion 10j and the lower plate convex portion 10k of the wave-dissipating block 10 are substantially the same type and the same size as each other. The planar shape is substantially similar to the planar shape of the wave-dissipating block 10, and the upper plate concave portion 10m and the lower plate concave portion 10n of the wave-dissipating block 10 have substantially the same shape and dimensions, and the planar shape is the wave-dissipating block 10 Is formed in a shape approximately similar to the plane shape of The side surface of the wave block upper plate 10e and the side surface of the wave-dissipating block lower plate 10f form a common substantially vertical plane facing in the same direction, and the upper surface of the wave-dissipating block upper plate 10e and the plane of the lower surface of the wave-dissipating block lower plate 10f. The short side and the long side of the shape, the upper plate convex portions 10j on the upper surface of the wave-dissipating block upper plate 10e, the lower plate convex portions 10k on the lower surface of the upper plate concave portion 10m and the wave-dissipating block lower plate 10f, and the lower plate concave portion 10n. The short side and the long side of each planar shape are substantially parallel lines in which the short sides and the long sides thereof are directed in the same direction. The two outer surfaces are two substantially vertical planes respectively extending from two side surfaces of the wave-dissipating block upper plate 10e sandwiching a corner having the upper-plate convex portion 10j of the wave-dissipating block upper plate 10e, respectively. Identical abbreviations facing the same direction A wave-dissipating block lower plate 10f sandwiching a corner portion of the wave-dissipating block lower plate 10f, the two outer surfaces of the lower-plate convex portion 10k of the wave-dissipating block 10 sandwiching a corner portion of the wave-dissipating block lower plate 10f. The two substantially vertical planes extending from the two side surfaces and the same substantially vertical plane respectively facing in the same direction, and the plurality of connecting pillars 10g of each wave-dissipating block 10 are arranged on the wave-dissipating block. The plate 10e and the wave-dissipating block lower plate 10 are joined at the four corners and substantially the center of each wave-dissipating block 10 to form each wave-dissipating block 10 in a substantially rectangular parallelepiped shape. The upper plate concave portion 10m and the lower plate convex portion 10k have four wave-dissipating blocks 10 of substantially the same type and the same size so that the side surfaces of substantially the same type and the same size are substantially in contact with each other. The outer edge of the planar shape is the plane of the wave-dissipating block 10 A flat outer edge that is assembled so as to form a shape that is substantially similar to the shape, and four lower plate projections 10k each consisting of one lower plate projection 10k of each wave-dissipating block 10 at the center thereof Is substantially similar to the planar shape of the wave-dissipating block 10, and this large lower plate convex portion is formed so as to be able to fit into the upper plate concave portion 10 m of the adjacent lower wave-dissipating block 10. The lower plate concave portion 10n and the upper plate convex portion 10j have four wave-dissipating blocks 10 having substantially the same type and the same size, and the side surfaces having substantially the same type and the same size are substantially in contact with each other. The four upper plates, each having an outer edge of the planar shape, are assembled so as to be substantially similar to the planar shape of the wave-dissipating block 10, and each of the upper-plate convex portions 10j of each wave-dissipating block 10 is in the center. The planar outer edge where the convex portions 10j are assembled is the flat surface of the wave-dissipating block 10. It has a shape substantially similar to the shape, and is formed so that this large upper plate convex portion can be fitted into the lower plate concave portion 10n of the adjacent upper wave-dissipating block 10, and the wave preventing chamber 4 includes the wave preventing plate 41 and the side wall plate. 42, and the wave breaker 41 provided inside the harbor of the wave breaker room 4 is a wave breaker block upper plate 10e and a wave breaker block lower plate 10f or a half wave breaker block upper plate 10ae and a half Side wall plates 42 that are coupled to the wave-dissipating block lower plate 10af, are formed in a substantially vertical flat plate shape in a direction substantially perpendicular to the longitudinal central axis of the wave-blocking block 1, and are provided on both sides of the wave-breaking chamber 4. Are on the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f or the half-wave-dissipating block upper plate 10ae and the wave-dissipating block lower plate 10af and the wave-dissipating plate 41 and the wave-dissipating block of the land-side chamber 2 Plate 10e and wave-dissipating block lower plate 10f or half-wave It is connected to the lock upper plate 10ae and the semi-wave-dissipating block lower plate 10af, and the outer side surface of the side wall plate 42 forms a substantially vertical plane that is substantially the same as the outer side surface of the wave-blocking block 1 in the longitudinal direction of the wave-blocking block 1. The inner side surface of the side wall plate 42 is formed substantially in parallel with the outer side surface of the wave blocking block 1 and has substantially the same thickness. The wave blocking chamber 4 includes a substantially vertical flat plate-shaped wave blocking plate 41, and has a substantially vertical flat plate shape. The side wall plates 42 are arranged in a zigzag pattern in the vertical direction, and have a space penetrating in the vertical direction in the wave preventing chamber 4.

  The wave-blocking block 1 according to the third invention is characterized in that the wave-breaking plate 41 according to claim 2 is provided with a fish passage hole 41 a for allowing the land-side chamber 2 and the wave-breaking chamber 4 to communicate with each other.

  The wave-blocking block structure 100 according to the fourth aspect of the present invention is the wave-blocking block 1 according to claim 2, wherein each wave-blocking block 1 is arranged in the direction from the sea floor side to the sea side and from the outside sea side to the harbor inside. The central axes in the major axis direction of the first block layer of the lower first block layer are arranged substantially adjacent to each other and arranged substantially parallel to the major axis direction of the two blocks of the wave blocking blocks 1 in the lower layer. A zigzag pattern is formed so that the central axis in the major axis direction of the row of wave blocking blocks 1 in a row of the upper second block layer adjacent to the first block layer substantially overlaps the upper layer of the contact surfaces of the side surfaces. A plurality of substantially the same type and the same size, which are installed side by side in close contact with the first block layer of the lower layer in common with the side surfaces of the same type and the same size. The breakwater block 1 and the first block layer are parallel to each other. And a plurality of wave-blocking blocks 1 of substantially the same type and the same size and arranged side by side in contact with each other on the second block layer of the upper layer adjacent to the first block layer in common with the same type and the same size. The wave preventing plates 41 of the wave preventing chamber 4 are formed in the wave blocking block structure 100 in which the wave blocking blocks 1 are stacked in a staggered manner on the upper and lower sides. Each wave-blocking block 1 is set so that each wave-blocking plate 41 is stacked in a direction substantially perpendicular to the direction from the open sea side to the inside of the port, and the first block layer Of the wave blocking block 10 such that the substantially rectangular parallelepiped side surfaces of the wave blocking block 10 of the substantially rectangular parallelepiped shape and the same dimension forming the land side chamber 2 and the sea side chamber 6 of the wave blocking block 1 are substantially in contact with each other. Four planar outer edges are substantially the same as the planar shape of wave-dissipating block 10 Each of the upper plate convex portions 10j protruding upward from the wave-dissipating block upper plate 10e of the four wave-dissipating blocks 10 of the first block layer is gathered so as to form a similar shape. The four upper plate convex portions 10j made of the above are assembled to form a large upper plate convex portion of the first block layer, and the outer edge of the planar shape is substantially similar to the planar shape of the wave-dissipating block 10, A large upper plate convex portion of the first block layer is disposed adjacent to the upper layer of the central portion of the outer edge of the four wave-dissipating blocks 10 of the first block layer. The four outer peripheral edges of the wave-dissipating block 10 of the first block layer are extinguished in the same manner as described above. The first block layer is assembled so as to be substantially similar to the planar shape of the wave block 10 The four lower plates projecting downward from the four corners of the wave-dissipating block lower plate 10f of the one wave-dissipating block 10 of the second block layer, which are installed adjacent to the upper layer of the central portion of the planar outer edge The convex portion 10k is inserted into each of a quarter of the upper plate concave portion 10m of each of the four wave-dissipating block upper plates 10e of the first block layer, and the land side chamber 2 and the sea side chamber 6 of the wave preventing block 1 are connected. The wave-dissipating block 10 is configured such that each upper plate convex portion 10j, each lower plate convex portion 10k, each upper plate concave portion 10m, and each lower plate concave portion 10n are mutually fitted in a staggered manner in the vertical direction to prevent waves. The block 1 can be stacked in several layers.

  The wave-blocking block structure 100 according to the fifth invention is formed by a wave-breaking plate extending portion 44 formed by extending the wave-blocking plate 41 upward of the wave-blocking block 1 installed in the uppermost layer according to claim 4. In addition, the upper part of the wave breaker extending portion 44 is inclined toward the sea side.

  A wavebreak block structure 100 according to a sixth invention is a construction method of the wavebreak block structure 100 for building the wavebreak block structure 100 according to the fourth invention or the fifth invention, and is substantially at the center. A number of cross beams 83 that can be set and removed are passed to the base boat opening 81 of the base boat 80 provided with the boat opening 81, and the wave blocking block 1 is placed on the top of the cross beam 83, and the wave blocking block 1 In a mode in which the breakwater block 1 is tightly coupled to the trolley 80 so that it does not move due to the swaying of the waves, a transport process for transporting the breakwater block 1 to a predetermined installation location, and a trolley opening at a substantially central portion of the trolley 80 The wave-blocking block 1 is suspended from the part 81, and the wave-blocking block 1 is installed in a predetermined installation place.

  According to the first invention, the wave-dissipating block constituting the wave-dissipating connecting block is composed of a substantially horizontal upper plate and a lower plate, and a plurality of substantially vertical connecting columns that connect the upper plate and the lower plate, Waves are broken by the upper and lower plates of the wave-dissipating block in the substantially horizontal direction, and the wave energy in the wave-dissipating connection block is a fast intermittent flow that resembles a stepped wave in the river (horizontal reciprocating water flow). When passing in such a flow, a vortex is generated in this fast flow by a connecting column in a substantially vertical direction. According to the first aspect of the present invention, the connecting column in the substantially central portion of the wave-dissipating block and the four connecting columns in the vicinity of the four corners are combined so that the wave breaks intermittently passing through the wave-dissipating connecting block. The large amount of vortices generated by a large turbulence can be greatly increased mainly by the large action of the connecting column in the central part, which can greatly increase the rate of wave energy deactivation. It becomes possible. Further, the wave-dissipating connection block is an underwater cave-like shape comprising a horizontal wave-dissipating block upper plate and a horizontal wave-dissipating block lower plate, and a plurality of substantially vertical connecting columns connecting the upper plate and the lower plate. It has a structure and has a reef effect as an underwater cave.

  According to the second invention, since the wave-dissipating block is incorporated in the sea-side room of the wave-breaking block, the upper and lower plates of the wave-dissipating block resemble the corrugated waves of the waves of the waves of waves. A flow like a fast intermittent flow (horizontal reciprocating water flow, the flow from the open sea side works with a large force of the fast flow, but the return flow works with a much smaller force than the flow from the open sea side). A vortex is generated by the connecting column of the sea side chamber in the substantially vertical direction. Waves broken by waves that pass through the interior of the wave-dissipating block are formed by the combination of the vertical pillars in the center of the wave-dissipating block built in the sea room and the four vertical pillars near the four corners. It is possible to greatly increase the amount of vortices generated by a large turbulent flow, mainly due to the large action of a substantially vertical connecting column at the center of the wave-dissipating block in the seaside room. It becomes possible to greatly increase the rate of wave energy deactivation. Due to the wave-dissipating effect of the wave-dissipating block built into the seaside room, the impact force against the wave-breaking plate can be mitigated, eliminating the need for stacking conventional deformed wave-dissipating blocks on the front side of the seawater side of the breakwater, Significant cost savings are possible. Moreover, since the wave-dissipating block exhibiting the shape of an underwater cave is incorporated in the land side room and the sea side room of the breakwater block, it has a fish reef effect as an underwater cave.

  According to the second invention, the upper plate convex portion and the lower plate projecting in the vertical direction from the wave-dissipating block upper plate and the wave-dissipating block lower plate of the wave-dissipating block incorporated in the land-side room and the sea-side room of the wave-blocking block, respectively. Since the upper plate concave portion and the lower plate concave portion, which are depressions, are provided in the central portion of the upper plate and the lower plate of the wave-dissipating block incorporated in the convex portion and the land side chamber and the sea side chamber, these convex portion and concave portion As a result, the plurality of wave blocking blocks can be stacked in a large mass concrete shape. According to the second aspect of the present invention, as compared with the conventional irregular wave-dissipating block to be stacked, the mass blocking concrete and the wave-dissipating block structure are strong and the side surfaces of the edges are large in a substantially vertical or stepwise manner. It becomes possible to pile up in a stratified product in the shape. In addition, each side surface inside the quadrangular pyramid of the top plate convex portion and bottom plate convex portion of the wave-dissipating block upper plate and the wave-dissipating block lower plate constituting each land-side chamber and each sea-side chamber of the wave-blocking block, Since the taper is formed on each side surface of the truncated pyramid of the upper plate recess and the lower plate recess of the block upper plate and the wave lower block block, if any part of these taper surfaces is caught, The convex portions of the block upper plate and the wave-dissipating block lower plate are guided by the dead weight to the wave-dissipating block upper plate and the wave-dissipating block lower plate of each wave-blocking block, and can be easily and quickly prevented in a single period. The wave blocks can be efficiently stacked on the wave-breaking block structure as a stratified layer. In addition, when a breakwater block is jumped by an unexpected large wave, the weight of each breakwater block constituting the breakwater, which is a breakwater block structure, is significantly smaller than the caisson. Therefore, it can be lifted by the clay, and even if it is not newly rebuilt and installed, the jumped breaker block can be lifted by the crane and restored to the original place.

  According to the second invention, by combining the wave-dissipating block, the wave-breaking plate, and the wave-breaking chamber, the wave-breaking function is the same as that of the caisson, and the wave-breaking dam caused by the random product of the wave-dissipating blocks By having a wave-dissipating function and a fish reef function as an underwater cave, and having the same stability as a caisson against rough waves from the open sea, The wave-dissipating blocks that make up the wave-blocking blocks are arranged in a zigzag pattern at the top and bottom, so that the wave-blocking blocks can be firmly fitted together in the vertical direction, and each wave-blocking block is stacked in a zigzag pattern in several layers This makes it possible to construct a solid mass concrete structure with a wave-breaking block. By arranging a plurality of wave-proof blocks in a zigzag pattern, the wave-proof chambers penetrating in the vertical direction and the side wall plates of the wave-proof chambers are also arranged in a zigzag pattern. As a result, the energy of the wave splash that jumps upward inside the wavebreak rooms arranged in a staggered manner is dispersed and reduced by the side wall plates arranged in a staggered manner, and the wave splash jumps up. By reducing the height, it is possible to reduce the amount of overtopping from the breakwater caused by wave splash.

  According to the third invention, the wave breaker plate of the wave breaker block is provided with a fish passage through which fish can come and go, so that the fish passage through which the fish can move between the open sea and the harbor through the wave breaker block is provided. Will also be secured.

  According to the fourth aspect of the invention, the waves collide with the mass concrete structure constructed by stacking the wave-blocking block, the wave-dissipating edge connection block and the wave-dissipating connection block in a staggered manner, so that several layers in a substantially horizontal direction are formed. Waves are crushed by the floor and ceiling, and the energy of the waves passes through the inside of the breakwater block seaside chamber as a fast intermittent flow (horizontal reciprocating water flow) that resembles a stepped wave of the river flow. Occasionally, many vortices are generated by the connecting column of the seaside chamber in the substantially vertical direction, mainly the connecting column in the center of the seaside chamber wave-dissipating block, and the energy of the wave can be greatly reduced. In addition, the wave breaker plate of the wave breaker room is such that each wave breaker plate forms a substantially vertical flat plate that is substantially the same in the wave breaker block structure in which the wave breaker blocks are stacked in a zigzag pattern above and below. Each wave block is set, and each wave block is stacked in a direction substantially perpendicular to the direction from the open sea side to the inside of the port, and the wave break plate of the wave block is the same as the caisson. It has an impermeable type wave-proof function with a simple wall structure. In addition, when the wave breaker plate is set at the edge of the open sea side of the connection block (the wave-removal edge connection block or the wave-removal edge connection block or the wave-removal connection block, etc.) The force action has the same function as the caisson. In addition, in the case of the wave-blocking block, coupled with the wave-dissipating function by the sea-side room of the wave-blocking block, the wave-breaking plate is provided in the middle of the wave-blocking block, not the end of the connection block on the outer sea side. Each wave block of the wave block structure is designed to increase the stability of the wave block because the sea room and land room on both sides of the wave plate are tightly fitted to each other in a staggered manner. Can do.

  According to the fourth aspect of the present invention, the wave height transmission rate to the harbor for the waves of the open sea is reduced by using the wave blocking blocks of the impermeable connection block structure in the middle layer and the upper layer of the wave blocking block structure. It is possible to ensure the calmness of the. In addition, at a position deeper than a quarter of the wavelength of the wave of interest from the sea surface, where the effect of the rotational motion of the wave is small, the connection block for the wave-dissipating edge of the transmission-type connection block structure and the wave-dissipating connection at the lower layer Using blocks, it is possible to improve the water quality in the port by communicating between the seawater in the port and the open sea and securing the passage of fish, and by exchanging the seawater in the port and the seawater in the open sea, It allows free traffic within the port and also has a fish reef effect as an underwater cave.

  According to the fourth invention, in order to improve the stability of the wave-blocking block structure, the concrete used for the production of the wave-breaking block contains a large amount of iron but is currently treated as waste. , The method of increasing the specific gravity of concrete and increasing the weight in water by using the electric furnace oxidation slag generated during scrap metal smelting and the copper slag generated during copper refining as aggregate, and increasing the block size A method of making a large block, a method of connecting a plurality of blocks instead of a single block, a method of fitting the wave blocking blocks in the vertical direction, and a central axis in the major axis direction of the wave blocking blocks Set a breakwater block so that the cross-sectional area of the breakwater block from the outside sea side is almost parallel to the inside of the port from the open sea side, and acts on the breakwater block. That the wave energy by reducing, can be difficult to move the breakwater blocks by wave forces. By these, it is possible to prevent the breaker block from moving due to the large waves that push one after the other, and it is also possible to prevent the breakage of the concrete from repeated collision of the breaker blocks due to the waves. It becomes. In addition, the breakwater block is not a site where quality control of each concrete member is difficult to perform, but in a PC factory where quality control is perfect, the wavebreak block upper plate, wavebreak block lower plate, connecting pillar, wavebreak plate, side wall plate They can be manufactured in high strength and high quality, and each of these concrete members can be transported to the site and assembled on site. There are also limited ports where caisson production yards exist to build caisson similar to shipbuilding docks. However, the wave-blocking block can be assembled into the wave-blocking block as long as the wave-blocking block can be secured in the vicinity of the construction site or in a nearby fishing port.

  According to 4th invention, the convex part which protrudes in the up-down direction from the four corners of the wave-dissipating block upper plate and the wave-dissipating block lower plate incorporated in the land-side room and the sea-side room of the wave-breaking block, Since the concave part which is a dent is provided in the central part of the board and the bottom plate of the wave-dissipating block, the wave-blocking blocks can be firmly stacked by fitting each other vertically and vertically in a zigzag manner. Is possible. In addition, at the construction site of mass concrete structures such as breakwaters and breakwaters, wavebreaking blocks can be added at any time by adding or removing breakwater blocks depending on conditions such as the shape, size, and waves of the site. The shape and size of the block structure can be freely designed, and the shape can be easily changed even after completion of the construction.

  According to the fifth aspect of the present invention, the wave breaker extending portion is provided on the wave breaker plate of the uppermost wave breaker block, and the upper part of the wave breaker is inclined to the open sea side, so that most of the wave splash that has jumped upward is the wave breaker. It is possible to return to the open sea side by being repelled by the plate extending portion. Thereby, the quantity which a wave splash flows into the harbor inner side can be decreased, and it becomes possible to improve the quietness in a harbor more.

  According to the sixth aspect of the present invention, the hoist crane can be operated from almost directly above the place where the wave blocking block is set while directly observing the wave blocking block from the opening of the boat provided substantially at the center of the boat. This makes it possible to easily operate the crane and winch, and the work efficiency of the setting of the wavebreak block is improved as compared with the case where the wavebreak block is installed in the sea that cannot be directly observed using a jib crane.

It is a perspective view which shows the wave-blocking block of this invention typically (when the bird's-eye view is seen from the outside sea direction in 2nd Embodiment). It is a top view which shows 1st Embodiment of a wave-blocking block (when the wave-dissipating block of the land side room inside a drawing upper port is single piece, and the wave-dissipating block of the sea side room below a drawing is half piece). It is a side view which shows 1st Embodiment of a wave-proof block. It is a top view which shows 2nd Embodiment of a wave-breaking block (when the wave-dissipating block of the land side room inside a port upper drawing is a half piece, and the wave-dissipating block of the sea side room of a lower sea side below a drawing is single). It is a side view which shows 2nd Embodiment of a wave-proof block. It is sectional drawing which shows arrangement | positioning of the side wall board of a wave-breaking chamber (The side wall board is arrange | positioned in zigzag form up and down in the wave-blocking block structure, the connection block for a wave-dissipating edge in a lower layer, and a barrier layer in a middle layer and an upper layer. The side wall plate of the wave-breaking chamber of the wave block is arranged). A wave breaker plate (a) is a front view of the wave breaker plate, (b) is a side view thereof, and (c) is its wave breaker plate. The uppermost wave-breaking plate of the wave-blocking block structure, which is a plan sectional view, is extended upward and the upper part is inclined to the open sea side). It is the front view which looked at the mode where the right and left edges of the wave-blocking block structure were piled up in steps from the open sea side (the open-sea side of the wave-blocking block structure and the edge inside the harbor are vertical planes). It is the front view which looked at the mode which piled up so that the right and left edges of a wave-blocking block structure may make a perpendicular plane from the open sea side (all the edges of the four rounds of a wave-breaking block structure are vertical planes). It is a top view which shows a wave-dissipating block. It is an elevation view which shows a wave-dissipating block. It is a top view which shows the wave-dissipating connection block with which the wave-dissipating block was connected (what connected several wave-dissipating blocks of substantially the same type and the same size in the shape of a straight rectangular solid). It is a top view which shows the connection block for a wave-dissipation edge to which a half-wave-dissipating block and several wave-dissipating blocks were connected (those in which the half-wave-dissipating block half is deleted). It is a top view of the block row body for a wave-proof edge which deleted the half row of the row | line | column of the right side of the wave-blocking block 2 row | line | column in 1st Embodiment of a wave-blocking block. It is a top view of the block row body for a wave-proof edge which deleted the half row of the row | line | column of the left side of the wave-blocking block 2 row | line | column in 1st Embodiment of a wave-blocking block. It is a top view of the block row body for a wave-proof edge which deleted the half row of the row | line | column of the right side of the wave-blocking block 2 row in 2nd Embodiment of a wave-blocking block. It is a top view of the block row body for a wave-proof edge which deleted the half row | line | column of the row | line | column of the left side of the wave-blocking block 2 row | line | column in 2nd Embodiment of a wave-blocking block. It is a side view which shows the detail of the aspect by which the wave-blocking block was piled up and down (the upper layer is the wave-blocking block of 1st Embodiment, the lower layer is the wave-blocking block of 2nd Embodiment, the upper side of a figure is a port inner side, and the lower side is Open sea side). It is a side view showing a wavebreak block structure (wavebreak blocks are used for the upper and middle layers, and a wave-dissipating edge connecting block is used for the lower layer, the right side of the figure is the harbor inner side, the left side is the open sea side) . It is a top view which shows the aspect which is carrying the breaker block with a trolley (the long slab opening which can pass a breakwater block is provided in the middle of a trolley, and a cross girder is in a sill opening A mode in which the wave-blocking block of the first embodiment is placed and carried on the upper part that has passed. It is a front view which shows the aspect of the construction method of a breakwater block structure ((a) is the aspect which is carrying the breakwater block with a trolley, (b) is installing a breakwater block from a trolley to a predetermined location. (The wire rope that binds the breaker block to the carriage is not shown). It is sectional drawing which looked at the aspect which attached the air bag to the wave-blocking block from the open sea side.

  Hereinafter, an embodiment for implementing a wave-blocking block 1 to which the present invention is applied will be described in detail with reference to the drawings.

  FIG. 1 is a perspective view schematically showing a wave breaker block 1 according to the second embodiment shown in FIGS. 4 and 5 of the wave breaker block 1 of the present invention, and is a view of the inside of a harbor as viewed from the outside sea.

  The breakwater block 1 includes a land side room 2 provided on the land side, a wave break room 4 provided on the sea side of the land side room 2, and a sea side room 6 provided on the sea side of the wave break room 4. The land side chamber 2, the wave preventing chamber 4, and the sea side chamber 6 are formed in a straight rectangular parallelepiped shape by connecting the land side chamber 2, the wave preventing chamber 4, and the sea side chamber 6, and constitute the wave preventing block 1. The land side chamber 2 and the sea side chamber 6 each have several wave-dissipating blocks 10 having the same shape and the same size as a rectangular parallelepiped, and the following half-wave-dissipating block 10a. The wave-dissipating block 10 includes a wave-dissipating block upper plate 10e and a wave-dissipating block lower plate 10f, and a plurality of connecting columns 10g that couple the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f. The plurality of connecting pillars 10g of each wave-dissipating block 10 are formed by connecting the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f at the four corners and the center of each wave-dissipating block 10. Are formed in a rectangular parallelepiped outline. A plurality of wave-dissipating blocks 10 having the same shape and the same size and having the same shape and the same size are connected in common, and two to an integer are connected to a straight rectangular parallelepiped shape to form a “wave-dissipating connection block 11”. . The wave-dissipating connection block 11 has a transmission-type connection block structure composed of several wave-dissipating blocks 10 of the same type and the same size. The wave-dissipating block 10 at one end of the wave-dissipating connection block 11 is cut in half at a vertical plane perpendicular to the central axis in the long axis direction of the wave-dissipating connection block 11 and at the center of the wave-dissipating block 10. The remaining part of the wave-dissipating block 10 connected to the wave-dissipating connection block 11 is referred to as a “half-wave-dissipating block 10a”. The semi-wave-dissipating block 10a is used with the cut surface facing outward so that the cut surface contacts the outer edge. The wave-dissipating block 10 at one end of the wave-dissipating connection block 11 is cut in half by the above-described method, and the remaining part of the wave-dissipating connection block 11 from which the cut pieces have been removed is formed into a straight rectangular parallelepiped “quenching” It is assumed that the wave-edge connecting block 12 ". One end of the wave-dissipating edge connecting block 12 is a half-wave-dissipating block 10 a, and the cut surface of the half-wave-dissipating block 10 a at the end is on the outer edge of the wave-blocking block structure 100 or the wave-dissipating block structure 101. Used in contact. The wave-dissipating edge connecting block 12 has a shape in which 1.5 to integer minus 0.5 wave-dissipating blocks 10 are connected. The wave-dissipating edge connecting block 12 has the same type and dimensions of the wave-dissipating edge connecting block 12 such that the half-wave-dissipating block 10a at the end faces in the opposite direction between the adjacent lower layer and upper layer. If the central axis is parallel and both ends are aligned and stacked in a staggered manner at the top and bottom, the outer edges formed by both ends of the wave-dissipating edge connecting block 12 can be stacked in a substantially vertical plane. The wave-dissipating edge connecting block 12 has a transmission-type connecting block structure composed of one half-wave-dissipating block 10a at one end and several wave-dissipating blocks 10 of the same type and the same size. Further, in another embodiment, the wave-dissipating blocks 10 at both ends of the wave-dissipating connection block 11 are perpendicular to the central axis in the major axis direction of the wave-dissipating connection block 11 and the wave-dissipating block 10 The remaining part of the wave-dissipating connection block 11 that has been cut in half at the center and from which the cut pieces at both ends have been removed is referred to as a straight rectangular parallelepiped-shaped "wave-dissipating both-edge connecting block 12a". Both ends of the wave-dissipating edge connecting block 12a are formed of a semi-wave-dissipating block 10a, and both ends of the cut surface are used so as to contact two opposite outer edges of the structure. The outer edge of the connection block 12a and the rectangular parallelepiped shape are the same shape and dimensions, and the wave-dissipating connection block 11 and the wave-dissipating both-edge connecting block 12a are alternately arranged in the major axis direction. When the center axis of each is parallel and the both ends are aligned and stacked in a zigzag manner at the top and bottom, the outer edges formed by the both ends can be stacked in a substantially vertical plane. Further, the wave-dissipating both-edge connecting block 12a is formed by joining the wave-dissipating blocks 10 on the opposite side of the two wave-dissipating edge connecting blocks 12 to form a straight rectangular parallelepiped shape. Make. The wave-dissipating both-edge connecting block 12a has a transmission-type connecting block structure including two half-wave-dissipating blocks 10a at both ends and several wave-dissipating blocks 10 of the same type and the same size. However, the wave-dissipating edge connecting block 12a obtained by cutting the wave-dissipating blocks 10 on both sides of the wave-dissipating connecting block 11 composed of two dissipating blocks 10 in half by the above method is composed of two semi-dissipating blocks 10a. .

  2 to 5, the wave-dissipating block upper plate 10 e of the wave-dissipating block 10 that constitutes the upper plate of the land-side chamber 2 and the sea-side chamber 6 of the wave-blocking block 1 has a side surface formed in a vertical plane, The upper plate convex portion 10j having a quadrangular pyramid shape that protrudes upward at the four corners of the upper surface is formed, and the inverted quadrangular pyramid shape that is depressed downward at the center of the upper surface is formed. An upper plate recess 10m is formed. The wave-dissipating block lower plate 10f constituting the lower plate of the land-side chamber 2 and the sea-side chamber 6 of the wave-blocking block 1 has a side surface formed in a vertical plane, a plane shape formed in a rectangular shape, and four corners on the lower surface. A lower plate convex portion 10k having an inverted quadrangular pyramid shape projecting downward at the center is formed, and a lower plate concave portion 10n having a quadrangular pyramid shape recessed upward is formed at the center of the lower surface. The upper surface of the wave-dissipating block upper plate 10e and the lower surface of the wave-dissipating block lower plate 10f are parallel to each other, and the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f have the same thickness and the same size. The side surfaces of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f form a common vertical plane that faces the same direction.

  2 to 5, the short side and the long side of the planar shape of the upper surface of the wave-dissipating block upper plate 10e and the lower surface of the wave-dissipating block lower plate 10f, and the upper plate protrusions on the upper surface of the wave-dissipating block upper plate 10e 10 j, the upper plate concave portion 10 m and the lower plate convex portion 10 k on the lower surface of the wave-dissipating block lower plate 10 f and the short side and the long side of each planar shape of the lower plate concave portion 10 n are the short sides and the long sides of each other. They are parallel lines that point in the same direction. The wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f have an upper plate convex portion 10j and a lower plate convex portion 10k that have the same shape or the same shape that is upside down and the same height and size. The planar shape is similar to the planar shape of the wave-dissipating block 10, and the upper plate concave portion 10m and the lower plate concave portion 10n have the same shape upside down and the same height and the same size. It is similar to the planar shape of the wave-dissipating block 10.

  2 to 5, each of the two outer surfaces of the upper plate convex portion 10j of the wave-dissipating block 10 has a wave-dissipating block sandwiching a corner portion of the wave-dissipating block upper plate 10e having the upper plate convex portion 10j. The upper plate 10e forms two substantially vertical planes extending from two side surfaces, respectively, and the same substantially vertical plane respectively facing the same direction, and each of the lower plate convex portions 10k of the wave-dissipating block 10 The two outer surfaces are respectively two substantially vertical planes extending from two side surfaces of the wave-dissipating block lower plate 10f sandwiching the corner having the lower plate convex portion 10k of the wave-dissipating block lower plate 10f, respectively. It forms the same substantially vertical plane facing the same direction.

  The upper plate concave portion 10m and the lower plate convex portion 10k of the wave-dissipating block 10 shown in FIG. 2 to FIG. The four outer edges of the four wave-dissipating blocks 10 are assembled so that their outer edges are similar to the planar shape of the wave-dissipating block 10, and four lower plate protrusions 10k are respectively formed at the center of the lower plate protrusions. The outer edges of the assembled planar shapes are aligned so that the outer corners of the portions 10k are almost in contact with each other, and form a similar shape to the planar shape of the wave-dissipating block 10, that is, the lower plate of each wave-dissipating block 10 at the center. A planar outer edge formed by assembling four lower plate convex portions 10k each consisting of one of the convex portions 10k is similar to the planar shape of the wave-dissipating block 10, and the lower layer adjacent to this large lower plate convex portion When formed so that it can be fitted into the upper plate recess 10m of the wave-dissipating block 10 In addition, the lower plate concave portion 10n and the upper plate convex portion 10j of the wave-dissipating block 10 have four wave-dissipating blocks 10 of the same type and the same size so that side surfaces of the same type and the same size are in contact with each other. The outer edges of the planar shape of the block 10 are assembled so as to be similar to the planar shape of the wave-dissipating block 10, and four upper plate convex portions 10j are respectively arranged at the center of each of the outer corners of the upper plate convex portions 10j. The outer edges of the assembled planar shapes that are aligned so that the portions are substantially in contact with each other form a shape similar to the planar shape of the wave-dissipating block 10, that is, each of the upper plate convex portions 10j of the wave-dissipating blocks 10 at the center. A planar outer edge formed by assembling four upper plate convex portions 10j consisting of one piece is similar to the planar shape of the wave-dissipating block 10, and this large upper plate convex portion is adjacent to the upper layer wave-dissipating block 10 It is formed so that it can be fitted into the lower plate recess 10n.

  2 to 5, the breakwater block 1 includes the land-side room 2 and the sea-side room 6, and the direction of each wave-dissipating edge connecting block 12 with respect to the outside sea side or the inside of the port is shown in FIGS. 2 and 3. In the first embodiment and the second embodiment shown in FIGS. 4 and 5, the wave-breaking edge connecting blocks 12 are set in the land side chamber 2 and the sea side chamber 6 so as to be opposite to each other. It is the top view and side view which show the wave-blocking block 1 of the aspect whose outline of the rectangular parallelepiped outer shape of the block 1 is the same type and the same dimension. 2 to 5, the outer sea side and the outer edge of the inside of the harbor of the wave-blocking block structure 100 are formed in a vertical planar form. The figure of 1st Embodiment is the case where the port side silencing block 10 of the land side room 2 is single, and the seaside silencing block 10 of the sea side room 6 is half, and the figure of 2nd Embodiment is the land This shows a mode in which the harbor-side wave-dissipating block 10 in the side chamber 2 is half and the sea-side wave-dissipating block 10 in the sea-side chamber 6 is single. There are two types of the wavebreak block 1, one according to the first embodiment and one according to the second embodiment.

  In other embodiments that constitute the land-side room 2 and the sea-side room 6 of the wave-blocking block 1 shown in FIGS. 2 to 5, the structures of the land-side room 2 and the sea-side room 6 of the first block layer are respectively wave-dissipated. The connection block 12a for both edges is used, and the land side chamber 2 and the sea side chamber 6 of the second block layer adjacent to the first block layer are used in the land side chamber 2 and the sea side chamber 6 of the first block layer. Further, the wave-dissipating connection block 11 constituted by the same number of wave-dissipating blocks 10 may be used in which the outer edge contour and the rectangular parallelepiped shape of the wave-dissipating both-edge connecting block 12a have the same shape and dimensions. Alternatively, the wave-dissipating edge connecting block 12 is used for the land-side chamber 2 of the first block layer, the wave-dissipating both-edge connecting block 12a is used for the sea-side chamber 6, and the land-side chamber 2 of the second block layer is The wave-dissipating edge connecting block 12 having the opposite direction to the wave-dissipating edge connecting block 12 used in the block layer is connected to the sea-side chamber 6 of the second block layer in the wave-dissipating band used in the first block layer. A wave-dissipating connection block 11 composed of the same number of wave-dissipating blocks 10 may be used in which the outline of the outer edge of the edge-connecting block 12a and the rectangular parallelepiped shape have the same shape and dimensions. Alternatively, the wave-dissipating edge connecting block 12 a may be used in the land-side chamber 2 of the first block layer, and the wave-dissipating edge connecting block 12 may be used in the sea-side chamber 6.

  The land side chamber 2 shown in FIGS. 2 to 5 includes a wave-dissipating block upper plate 10e, a wave-dissipating block lower plate 10f, a half-wave-dissipating block upper plate 10ae, a half-wave-dissipating block lower plate 10af, and a wave-dissipating block upper plate 10e. And a plurality of connecting columns 10g for connecting the wave-dissipating block lower plate 10f, and a plurality of connecting columns 10g for connecting the semi-wave-dissipating block upper plate 10ae and the half-wave-dissolving block lower plate 10af. A plurality of connecting pillars 10g of the wave-dissipating block 10 and the semi-wave-dissipating block 10a constituting the land-side chamber 2 connect the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f to the four corners of the wave-dissipating block 10 and The half wave-dissipating block upper plate 10ae and the half wave-dissipating block lower plate 10af are joined at both ends and the central part of the half-wave-dissipating block 10a.

  The upper plate of the land side chamber 2 shown in FIGS. 2 to 5 is, in the first embodiment of the wave breaker block 1, as shown in the plan view of FIG. 2 and the side view of FIG. And a semi-wave-dissipating block upper plate 10ae provided on the wave-proof chamber 4 side. Moreover, the upper board of the land side chamber 2 was provided in the wave-dissipating block upper board 10e and the harbor inner side, as shown in the top view of FIG. 4, and the side view of FIG. Half-wave-dissipating block upper plate 10ae. The wave-dissipating block upper plate 10e is formed with four upper-plate convex portions 10j that protrude upward at the four corners of the upper surface, and the semi-wave-dissipating block upper plate 10ae protrudes upward at both ends of the upper surface. Two upper plate convex portions 10j are formed. Further, the wave-dissipating block upper plate 10e is formed with an upper-plate concave portion 10m that is depressed downward at the center of the upper surface of the wave-dissipating block upper plate 10e. A semi-upper plate recess 10am that is depressed in the direction is formed.

  The bottom plate of the land side chamber 2 shown in FIGS. 2 to 5 is, in the first embodiment of the wave breaker block 1, as shown in the plan view of FIG. 2 and the side view of FIG. And a semi-wave-dissipating block lower plate 10af provided on the wave-proof chamber 4 side. Further, the lower plate of the land side chamber 2 is provided on the wave-dissipating block lower plate 10f and the inner side of the harbor as shown in the plan view of FIG. 4 and the side view of FIG. And a half wave-dissipating block lower plate 10af. The wave-dissipating block lower plate 10f is formed with four lower-plate convex portions 10k that protrude downward at the four corners of the lower surface, and the semi-wave-dissipating block lower plate 10af protrudes downward at both ends of the lower surface. Two lower plate projections 10k are formed. The wave-dissipating block lower plate 10f is formed with a lower plate recess 10n that is recessed upward at the center of the lower surface of the wave-dissipating block lower plate 10f. A semi-lower plate recess 10an that is depressed in the direction is formed.

  The seaside room 6 shown in FIGS. 2 to 5 includes a wave-dissipating block upper plate 10e, a wave-dissipating block lower plate 10f, a half-wave-dissipating block upper plate 10ae, a half-wave-dissipating block lower plate 10af, and a wave-dissipating block upper plate 10e. And a plurality of connecting columns 10g for connecting the wave-dissipating block lower plate 10f, and a plurality of connecting columns 10g for connecting the semi-wave-dissipating block upper plate 10ae and the half-wave-dissipating block lower plate 10af. The plurality of connecting pillars 10g of the wave-dissipating block 10 and the semi-wave-dissipating block 10a connect the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f at the four corners and the central part of the wave-dissipating block 10, and The semi-wave-dissipating block upper plate 10ae and the semi-wave-dissipating block lower plate 10af are coupled at both ends and the central portion of each semi-wave-dissipating block 10a.

  The upper plate of the seaside room 6 shown in FIGS. 2 to 5 is a top view of the wave-dissipating block 10e as shown in the plan view of FIG. 2 and the side view of FIG. And a semi-wave-dissipating block upper plate 10ae provided on the outer sea side. In addition, in the second embodiment of the breaker block 1, the upper plate of the sea side chamber 6 is on the side of the wave-dissipating block upper plate 10 e and the breaker chamber 4 as shown in the plan view of FIG. And a semi-wave-dissipating block upper plate 10ae. The wave-dissipating block upper plate 10e is formed with four upper-plate convex portions 10j that protrude upward at the four corners of the upper surface, and the semi-wave-dissipating block upper plate 10ae protrudes upward at both ends of the upper surface. Two upper plate convex portions 10j are formed. Further, the wave-dissipating block upper plate 10e is formed with an upper-plate concave portion 10m that is depressed downward at the center of the upper surface of the wave-dissipating block upper plate 10e. A semi-upper plate recess 10am that is depressed in the direction is formed.

  The bottom plate of the sea side chamber 6 shown in FIGS. 2 to 5 is, in the first embodiment of the wave breaker block 1, as shown in the plan view of FIG. 2 and the side view of FIG. And a semi-wave-dissipating block lower plate 10af provided on the outer sea side. Moreover, the lower plate of the sea side chamber 6 is the side of the wave-dissipating block lower plate 10f and the wave-breaking chamber 4 as shown in the plan view of FIG. 4 and the side view of FIG. And a half wave-dissipating block lower plate 10af. The wave-dissipating block lower plate 10f is formed with four lower-plate convex portions 10k that protrude downward at the four corners of the lower surface, and the semi-wave-dissipating block lower plate 10af protrudes downward at both ends of the lower surface. Two lower plate projections 10k are formed. The wave-dissipating block lower plate 10f is formed with a lower plate recess 10n that is recessed upward at the center of the lower surface of the wave-dissipating block lower plate 10f. A semi-lower plate recess 10an that is depressed in the direction is formed.

  In each of the upper plate recess 10m and the lower plate recess 10n of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f, the waves are extinguished from the bottom surfaces of the upper plate recess 10m and the lower plate recess 10n, respectively, for air bleeding. One or more through holes (not shown) having a width of about 3 to 10 cm may be perforated so as to reach the inner surface of the block upper plate 10e or the wave-dissipating block lower plate 10f. The cross-sectional shape of the through hole may be any geometric cross-sectional shape such as octagon, triangle, square, polygon, circle, ellipse, or a combination of these shapes.

  The upper plate convex portion 10j of the wave-dissipating block upper plate 10e is a quadrangular pyramid trapezoid and has a square planar shape, is formed at the four corners of the upper surface of the wave-dissipating block upper plate 10e, and The plate convex portion 10k is an inverted quadrangular pyramid and has a square planar shape, and is formed at the four corners of the lower surface of the wave-dissipating block lower plate 10f. The upper plate convex portion 10j and the lower plate convex portion 10k are either the same shape or the same shape with the top and bottom reversed, and have the same height and the same size, and these planar shapes are similar to the planar shape of the wave-dissipating block 10. Make. The upper plate concave portion 10m and the lower plate concave portion 10n of the wave-dissipating block 10 are (reverse) square pyramid trapezoids, and the planar shape is square, and are formed at the center of the upper and lower surfaces of the wave-dissipating block 10. The upper plate concave portion 10 m and the lower plate concave portion 10 n have the same shape upside down and the same height and the same size, and these planar shapes are similar to the planar shape of the wave-dissipating block 10. Further, the upper surface of the upper plate convex portion 10j and the lower surface of the upper plate concave portion 10m, the lower surface of the lower plate convex portion 10k and the upper surface of the lower plate concave portion 10n, and the upper surface of the lower plate concave portion 10n. The upper and lower surfaces of the upper plate 10e and the wave-dissipating block lower plate 10f are formed parallel to each other and horizontally. Further, the upper and lower surfaces of the land-side chamber 2 and the sea-side chamber 6 and the upper and lower surfaces of the wave-dissipating blocks 10 constituting the land-side chamber 2 and the sea-side chamber 6 form the same horizontal plane. 6 and the height of each wave-dissipating block 10 constituting the land-side room 2 and the sea-side room 6 are the same height, and the width of the land-side room 2 and the sea-side room, and each of the land-side room 2 and the sea-side room 6 are constituted. The width of the wave-dissipating block 10 is the same.

  The wave-blocking block 1, the wave-breaking connection block 11 or the wave-breaking edge connection block 12 is manufactured in a straight rectangular parallelepiped shape, and is stacked with their long axis center axes parallel to each other. A wave-dissipating block structure 101 is formed. However, when the wave-blocking block 1, the wave-breaking connection block 11, or the wave-breaking edge connection block 12 is used at an intersection where the two wave-breaking block structures 100 or the two wave-dissipating block structures 101 intersect each other. In order to connect the two wave-blocking block structures 100 or the two wave-breaking block structures 101 in a generally smooth curved shape, the wave-blocking block 1 or the wave-breaking connection block 11 or the wave-breaking edge. The planar shape of the connecting block 12 may be manufactured in a trapezoidal shape.

  The upper plate convex portion 10j of the wave-dissipating block upper plate 10e is tapered so as to shrink from the lower side toward the upper side on the two inner side surfaces. The lower plate convex portion 10k of the wave-dissipating block lower plate 10f is tapered so as to shrink from the upper side to the lower side on the two inner side surfaces. The upper plate concave portion 10m of the wave-dissipating block upper plate 10e is tapered so as to shrink from the upper side to the lower side. The lower plate recess 10n of the wave-dissipating block lower plate 10f is tapered so as to shrink from below to above.

  The design dimensions of the long and short sides of the upper plate convex portion 10j and the lower plate convex portion 10k of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f constitute the wave-breaking block 1. The length of each of the long side and the short side of the planar shape of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f is set to about one-fourth. Production dimensions are such that the length of the planar shape of the wave-dissipating block 10 is longer than the design dimension, and the length of each of the long and short sides of the planar shape of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f. Therefore, the manufacturing dimensions of the upper plate convex portion 10j and the lower plate convex portion 10k are the planes of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f than the design dimensions. The length is set to be about 2.5 to 5% smaller than the length of each of the long and short sides of the shape. As a result, the breakwater block 1 is manufactured so as to absorb irregularities on the top surface of the mound at the bottom of the seabed and operational errors and manufacturing errors during installation of the breakwater block 1.

  The design dimensions of the long side and the short side of the planar shape of the upper plate concave portion 10m and the lower plate concave portion 10n of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are the same as those of the The wave block upper plate 10e and the wave-dissipating block lower plate 10f are set to about one half of the length of each of the long side and the short side of the planar shape. The manufacturing dimensions of the upper plate concave portion and the lower plate concave portion are set to the same dimensions as the design dimensions, and the lower plate convex portions 10k and the upper plate convex portions 10j that are fitted into the upper plate concave portions 10m and the lower plate concave portions 10n. The manufacturing dimension is set to be approximately 2.5 to 5% smaller than the design dimension of each of the long side and the short side of the planar shape of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f. Therefore, the wave-proof block 1 is manufactured by these so that the unevenness | corrugation of the mound top end surface of a seabed and the operation mistake at the time of installation construction of the wave-block 1 and a manufacturing error can be absorbed.

  The upper plate convex portion 10j and the lower plate convex portion 10k of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are (reverse) square pyramid trapezoids, and the plane is square, and each upper plate convex portion 10j and lower plate The vertical ridge line formed by the intersection of the two vertical sides on the outer side of the (reverse) square frustum of the convex part 10k and the (reverse) quadrangular pyramidal quadrangular pyramid of the upper and lower convex parts 10j and 10k. The apex is on the same vertical line, and the ridge line portion formed by the intersecting line of the two inclined inner side surfaces of the upper plate convex portion 10j and the lower plate convex portion 10k having a (rectangular) pyramidal trapezoidal shape and a flat plane. A notch formed of an inclined surface may be formed. Moreover, the vertical ridgeline part which consists of the intersection of the outer vertical two side surfaces of the upper board convex part 10j and the lower board convex part 10k, and the perpendicular | vertical of the corner part of the wave-dissipating block upper board 10e and the wave-dissipating block lower board 10f A notch portion formed of a vertical surface may be formed in a vertical ridge line portion formed of an intersection line of two side surfaces. The horizontal cross-sectional shapes of these notches are shown by straight lines in FIGS. 10 and 11, but may be a polygonal line, an arc, an elliptical arc, or a combination of these shapes.

  The upper plate convex portion 10j and the lower plate convex portion 10k of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are (reverse) square pyramid trapezoids, the planar shape is square, and the intersection of two inclined inner surfaces. Each horizontal cross-sectional shape of the notch part of the ridge line part made of a line has a similar shape, a line connecting the same similar points of the similar shape forms a straight line, and this inclined straight line is (reverse) It becomes an aspect which passes the vertex of the quadrangular pyramid of the convex part which makes a quadrangular pyramid. The notch portions on the inner side surfaces of the upper plate convex portion 10j and the lower plate convex portion 10k are both side ends in the width direction of the horizontal cross section of the notch portions on the inner side surfaces of the upper plate convex portion 10j and the lower plate convex portion 10k. The planes drawn by the two straight lines of each part form inclined planes, and each inclined plane on the inner surface of the convex part becomes each inclined triangle having the apex of the quadrangular pyramid as an apex. Intersection of the inclined triangular surfaces of the notches on the inner surface of the (inverted) square pyramid of the upper and lower plate convex portions 10j and 10k of the square and the inner surfaces of the upper and lower plate convex portions 10j and 10k. A plane shape of each horizontal cross section of each triangular frustum formed by each ridge line composed of a line forms a right isosceles triangle or a right triangle.

  Further, the notch portions on the inner surface of each of the upper plate convex portions 10j and the lower plate convex portions 10k having a (reverse) quadrangular pyramid shape and having a square planar shape are inclined triangular surfaces, upper plate convex portions 10j and lower plate convex portions. The upper plate in which the notch formed by the ridge line formed by the intersecting line of the inner surface of the part 10k forms a triangular frustum and two straight lines at both ends in the width direction of the horizontal section of the notch are formed. The inclined planar shape inside the convex portion 10j and the lower plate convex portion 10k is formed in a (reverse) trapezoidal shape.

  The upper plate convex portion 10j and the lower plate convex portion 10k of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are the outer sides of the (reverse) square frustum shape formed by the upper plate convex portion 10j and the lower plate convex portion 10. Wave-dissipating block upper plate 10e and wave-dissipating a vertical ridge line formed by intersecting lines of two vertical side surfaces, and a corner having the above (reverse) quadrangular pyramidal upper plate convex portion 10j and lower plate convex portion 10k. The vertical ridge line formed by the intersection of two vertical side surfaces of the block lower plate 10f forms a straight line common to the vertical direction.

  Corresponding to the shape of notches at the corners of the inner surface of the lower plate convex portion 10k at the boundary portions of the two side surfaces of the four corners of the side surface of the upper plate concave portion 10m of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f. There may be a shape of the haunch, and there is a haunch of a shape corresponding to the shape of the notch at the corner of the inner surface of the upper plate convex portion 10j at the boundary between the two side surfaces of the four corners of the side surface of the lower plate concave portion 10n. May be.

  The connecting pillar 10g connects the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f of the wave-dissipating block 10 constituting the land-side chamber 2 or the sea-side chamber 6 at each of the four corners and the central portion. The block 10 is formed with a rectangular parallelepiped outline.

  The connecting column 10g is formed in a columnar shape having the same length and a horizontal octagonal cross section in the horizontal plane direction. The connecting column 10g is not limited to this, and may have any geometric cross-sectional shape such as a square, a polygon, a circle, an ellipse, or a shape obtained by combining these shapes. The connecting column 10g is preferably a column having the same shape and the same size so that a common formwork can be used in the production thereof. However, the connecting column 10g is not limited to this, and each has a separate shape having the same length. There may be.

  The upper end portion of the connecting column 10g has a hunch portion formed so as to expand in diameter upward on the side surface of the column, and is formed so as to extend vertically upward from the upper end of the hunch portion as necessary. It may have a vertical part. The lower end portion of the connecting column 10g has a hunch portion formed so as to expand in the downward direction on the side surface of the column, and is formed so as to extend vertically downward from the lower end of the hunch portion as necessary. It may have a vertical part. The connecting column 10g is not limited to this, and may be an upper end portion and a lower end portion of any shape.

  In the wave-breaking chamber 4 of the wave-breaking block 1, a vertical wave erection block upper plate 10 e and a wave-dissipating block lower plate 10 f or a half-wave-dissipating block upper plate 10 ae and a half-wave-dissipating block lower plate 10 af are installed. A flat plate-like wave-breaking plate 41 is provided inside the port of the wave-breaking chamber 4, and the wave-dissipating block of the sea-side chamber 6 is provided via vertical plate-like side wall plates 42 provided on both sides of the wave-breaking chamber 4. Upper plate 10e and wave-dissipating block lower plate 10f or semi-wave-dissipating block upper plate 10ae and semi-wave-dissipating block lower plate 10af, wave-dissipating plate 41 and wave-dissipating block upper plate 10e and wave-dissipating block lower plate 10f of land side chamber 2 Or it has the space penetrated in the up-and-down direction for connecting the half wave-dissipating block upper board 10ae and the half-wave-dissipating block lower board 10af, and diffusing the wave energy which made the wave break up and down. The wave preventing chamber 4 has a haunch portion formed at a corner portion formed by the inner side surface of the side wall plate 42 and the side surface on the outer sea side of the wave preventing plate 41, and is reinforced so as to cope with concentrated stress on the corner portion. Good.

  In addition, as shown in FIG. 6, the outer side surface of the side wall plate 42 forms the same vertical plane as the outer side surface of the wave preventing block 1 in the direction of the central axis of the wave preventing block 1, and the inner side surface of the side wall plate 42. Is parallel to the outer surface of the side wall plate 42, the side wall plates 42 on both the left and right sides are the same thickness, and the height of the side wall plate 42 is the height from the lower surface of the sea side chamber 6 and the land side chamber 2 to the upper surface of the upper plate. It is the same as (the height not including the convex portion), and the upper surface and the lower surface of the side wall plate 42 form a horizontal plane.

  In addition, as shown in FIG. 6, each of the four horizontal ridge lines where the upper and lower end surfaces of the side wall plate 42 and the two inner side surfaces of the side wall plate 42 intersect is provided with an inclined taper of the same type and the same size. Each horizontal line passing through the upper end surface and the lower end surface of the four side walls 42 of each taper is bilaterally symmetric with respect to a vertical plane passing through the central axis in the major axis direction of the wave-blocking block 1, and is a horizontal plane passing through the central axis. The four tapers have the same dimensions and the same dimensions that are symmetrical in the vertical and horizontal directions, and the top and bottom surfaces of the side wall plate 42 are narrowed planes that are notched by the taper. Form horizontal, parallel, and equal planes.

  As shown in FIG. 6, the wave-blocking block structure 100 includes a wave-breaking chamber 4 and a wave-breaking chamber that are vertically penetrated by arranging the wave-blocking blocks 1 in a staggered manner between adjacent upper and lower layers. The vertical flat side wall plates 42 on both sides of the four are also arranged in a staggered manner. As a result, the breakwater block structure 100 has a fast intermittent flow (reciprocal water flow in the horizontal direction) in the wavebreak chambers 4 arranged in a zigzag pattern, in which the energy of the waves that are broken is similar to the stepped waves of the river flow. The flow from the open sea side works with a large force of fast flow, but the return flow works with a much smaller force than the flow from the open sea side.) The energy of the wave splash that is diffused in the direction and jumps upward inside the wave prevention chamber 4 is combined with the function of the side wall plates 42 arranged in a staggered manner and the tapered portion provided on the side wall plates 42, It is possible to reduce the height of the scattered and reduced and jumping up, and to reduce the amount of overtopping from the breakwater caused by splashing. By providing a taper at the lower part of the inner side surface of the side wall plate 42, the side wall plate 42 is provided. Impact force Can be relaxed, also it becomes possible to reduce the force pushing the distance between the breakwater blocks 1 adjoining.

  The wave blocking plate 41 of the wave blocking block 1 is a pair of “wave blocking plate reinforcing side walls 43” between the wave blocking plate 41 and the connecting pillar 10 g of the land side chamber 2 at the nearest location inside the port from the wave blocking plate 41. May be provided to reinforce the wave preventing plate 41 and the connecting column 10g so as to be integrated. Furthermore, when it is necessary to reinforce the coupling between the wave preventing plate 41 and the land side chamber 2, the wave preventing plate reinforcing side wall 43 may be extended to the inner side of the port. Moreover, you may reinforce | strengthen by providing a haunch in the corner | angular part which makes the perpendicular line where the port inner surface of the wave-protecting plate 41 and the inner surface of the wave-protecting plate reinforcement side wall 43 cross.

  A pair of “side wall plate reinforcing side walls 43b” is provided between the side wall plate 42 of the wave breaker block 1 and the connecting column 10g of the seaside chamber 6 closest to the open sea side from the side wall plate 42, and the side wall plate 42 and the connecting column 10g. And may be reinforced by combining them together. Furthermore, when it is necessary to reinforce the coupling between the side wall plate 42 and the sea side chamber 6, the side wall plate reinforcing side wall 43b may be extended to the open sea side.

  “Shock mitigation side wall A43c” which is a short side wall of the extension part of the side wall plate reinforcing side wall 43b may be provided on the outer sea side of the connecting column 10g of the sea side room closest to the outer sea side from the side wall plate 42 of the wave preventing block 1. A taper made of a vertical surface may be provided at the corner formed by the inner side surface of the short impact relaxation side wall A43c and the outer sea side end surface of the impact relaxation side wall A43c, and each vertical taper provided on the inner side of the impact relaxation side wall A43c is In addition, the impact force applied to the impact relaxation side wall A43c due to the waves is relaxed, and the force that pushes the distance between the wave blocking blocks 1 adjacent to the side is also reduced.

  When the end of the seaside chamber 6 of the wave-blocking block 1 or the wave-dissipating connection block 11 or the wave-dissipating edge connection block 12 is composed of a single wave-dissipating block 10 or at the corner of the semi-wave-dissipating block 10a When the connecting pillar 10g is moved to the cut surface side, an “impact mitigation side wall B43d” is provided between the outer sea side edge surface of the wave-dissipating block 10 or the half wave-dissipating block 10a and the nearest connecting pillar 10g. Alternatively, a taper made of a vertical surface may be provided at a corner portion formed by the outer sea side edge surface of the wave-dissipating block 10 at the end and the inner surface of the impact relaxation side wall B43d. Each vertical taper provided on the inner side surface of the shock relaxation side wall B43d alleviates the impact force applied to the side wall by the waves and also reduces the force that pushes the gap between the wave blocking blocks 1 adjacent to the side.

  As shown in FIG. 2 to FIG. 5 and FIG. 19, each of the wave preventing plates 41 is substantially the same vertical flat plate inside the wave preventing block structure 100 in which the wave preventing blocks 1 are stacked. Arranged to form a shape. When the wave block 1 is stacked in a zigzag pattern on the top and bottom inside the wave break block structure 100 such as a breakwater having a rectangular parallelepiped shape, when a small step portion is not provided on the inner edge of the port, or a small step is provided. In this case, the position of the wave blocking plate 41 in the wave blocking block structure 100 provided with the wave blocking plate 41 is such that each of the wave blocking plates 41 forms substantially the same vertical flat plate shape. Is set. And the direction of the central axis of the horizontal direction of the wave-protecting plate 41 is set to be substantially perpendicular to the direction from the outside sea side toward the inside of the harbor. Therefore, since the wave preventing plate 41 is incorporated in the wave preventing block 1, the wave preventing block 1 has an impermeable type wave preventing function with a wall structure similar to the caisson. In addition, the wave preventing plate 41 when the wave preventing plate 41 is set to the end portion on the open sea side of the connecting block (the wave blocking edge connecting block 12 or the wave absorbing both edges connecting block 12a or the wave absorbing connecting block 11). The breaking wave depressing action on the waves of the sea has the same function as the caisson. In the case of the wave breaker block 1, the wave breaker 41 is provided in the middle of the wave breaker block 1, not at the outer sea end of the connecting block, coupled with the wave-dissipating function of the wave breaker block 1 by the sea side chamber 6. As a result, in each of the wave blocking blocks 1 of the wave blocking block structure 100, the sea side chamber 6 and the land side chamber 2 on both sides of the wave blocking plate 41 are tightly fitted to each other in a staggered manner. Therefore, the stability of the wave breaker block 1 can be increased.

  As shown in FIG. 2 to FIG. 5 and FIG. 7, the land-side room 2 and the wave-breaking room 4 are provided on the wave-breaking plate 41 of the wave-breaking block 1 so that fish can pass between the harbor inside and the open sea side. One or more fish passage holes 41a that communicate with each other are formed. Further, the wave blocking block structure 100 is provided with a fish passage, since the fish passage hole 41a through which the fish goes back and forth is drilled in the wave blocking plate 41.

  The fish passage hole 41a has any geometric cross-sectional shape such as a regular octagon, a triangle, a quadrangle, a polygon, a circle, an ellipse, or a combination of these shapes as shown in FIGS. Also good. The fish passage hole 41a enhances the flow depressing effect of the flow from the fish passage hole 41a by the connecting pillar 10g of the land side chamber 2 that joins the center portion of the wave-dissipating block 10 or the semi-wave-dissipating block 10a of the land-side chamber 2. It is desirable that the wave preventing plate 41 is formed at a position near the central axis in the vertical direction so that it can be formed. The total area of the fish passage holes 41a is preferably within 5% of the area of the wave preventing plate 41.

  The wave-breaking block structure 100 incorporates a wave-dissipating block 10 having an underwater cave shape in the sea-side room 6 and the land-side room 2 of the wave-breaking block 1 constituting the wave-breaking block structure 100, so that the underwater cave It has a fish reef effect.

  The wavebreak block structure 100 is like a fast intermittent flow (horizontal reciprocating water flow) similar to a stepped wave of waves that breaks through the seaside chamber 6 of the wavebreak block 1 from the outside sea side to the port inside. The flow is de-energized by the wave-dissipating block 10 of the sea side chamber 6 and the invasion is prevented by the wave-breaking plate 41 of the wave-breaking chamber 4, so that upward wave splashing occurs. As shown in FIGS. 7 and 19, the wave preventing block structure 100 is provided with a wave preventing plate extending portion 44 on the wave preventing plate 41 of the uppermost wave preventing block 1, and an upper portion of the wave preventing plate extending portion 44 is provided. By inclining to the open sea side, most of the splashes that jumped upward can be repelled and returned to the open sea side. The wave-breaking plate extending portion 44 is thickened at both ends in the width direction and provided with hunches at both ends, so that most of the splashing is collected near the center of the front side of the wave-breaking plate extending portion 44 on the open sea side. Against the sea breeze, more waves splash in the direction of the open sea. Thereby, the wave-blocking block structure 100 can reduce the quantity which a wave splash flows into a port inner side, and it becomes possible to improve the quietness in a port more. Further, the wave preventing plate 41 of the uppermost wave preventing block 1 may be reinforced by making the plate thicker than the wave preventing plate 41 of the lower wave preventing block 1.

  The wave breaker block 1 or the wave-dissipating edge connecting block 12 shown in FIG. In the case of being formed in a staircase shape, it is used for reducing the wave power of waves in the coastal area, wave-dissipating and breaking, and a plurality of wave-blocking blocks 1 or wave-dissipating edge connecting blocks 12 in the field. The central axis of the long axis direction of the seawater is stacked in parallel to the direction from the open sea side to the inner side of the port, so that the breakwater block structure 100 is formed in a direction parallel to the direction from the open sea side to the inner side of the port. Alternatively, the left and right outer edges of the wave-dissipating block structure 101 are stacked stepwise. In addition, the wave-blocking block structure 100 or the wave-breaking block structure 101 may be a structure in which outer edges are stacked with an arbitrary gradient, and the wave-breaking block structure 100 or the wave-breaking block structure shown in FIG. The outer edge of the body 101 may be a vertical plane.

  The wave-blocking block structure 100 or the wave-breaking block structure 101 shown in FIG. The wave-blocking block 1 or the wave-dissipating edge connecting block 12 is adjacent to each other, and is parallel to the central axis in the long axis direction of the two rows of wave-blocking blocks 1 or wave-dissipating edge connecting blocks 12 in the lower first block layer. As the upper layer of the contact layer of the vertical and the same size side surfaces, the lower block block 1 or the wave-dissipating edge connecting block 12 as the second block layer adjacent to the first block layer and the contour of the outer edge Are made of wave-blocking block 1 or wave-dissipating edge connecting block 12 of the same type and dimensions, and when stacked in a zigzag pattern on the top and bottom so that the central axes in the long axis direction overlap, Parallel to the direction to go Nasu outer edge, per block layer one layer, the lower layer toward the upper layer, are stacked in a stepwise manner to have decreased by one-half the width of the wave dissipating blocks 10. However, the edges of the outer sea side and the inner side of the port are constructed in a vertical plane.

  FIG. 9 is a front view of the wave-blocking block structure 100 or the wave-dissipating block structure 101 as seen from the open sea side. It is built up in a zigzag pattern up to the sea. The wave-blocking block structure 100 or the wave-breaking block structure 101 includes a plurality of wave-blocking blocks 1 or wave-blocking edge connection blocks 12 arranged side by side in the first block layer, and a layer adjacent to the lower layer and the upper layer. And a plurality of wave blocking blocks 1 or wave-dissipating edge connecting blocks 12 installed as two block layers. In the center layer of the wave-blocking block structure 100 or the wave-breaking block structure 101 shown in FIG. 9, the wave-blocking edge block row 1b or the wave-breaking edge connecting block row 12b shown in FIGS. Is used for the edge that is parallel to the direction from the open sea side to the inside of the port, and the edge that is parallel to the direction from the open sea side to the inside of the port forms a vertical plane, as shown in FIG. Since the outer sea side and the harbor inner side are also constructed to form a vertical plane, all of the outer edges of the wave-blocking block structure 100 or the wave-dissipating block structure 101 can be constructed in a vertical plane.

  FIG. 8 shows a case where a half row of the wave-blocking block 1 or the wave-dissipating edge connecting block 12 is deleted each time the stacking of the layers of the edge block row parallel to the direction from the open sea side to the port inner side is performed. In this way, the outer edge can be stacked in a stepped shape consisting of half the width of the wave-dissipating block 10, or one row of the wave-blocking block 1 or the wave-dissipating edge connecting block 12 each time one layer is stacked. .5 rows, 2 rows, etc. can be deleted, and the outer edges that are parallel to the direction from the open sea side to the inside of the harbor can be stacked in a gradual step.

  Further, each wave-dissipating block 10 constituting the land-side room 2 and the sea-side room 6 of the wave-blocking block 1 or the wave-dissipating edge connecting block 12 is adjacent to the wave-breaking room 4 or the land-side room 2 or the sea-side room 6. The half of the wave-dissipating block 10 on the inner side or the wave-dissipating block 10 on the outer sea side or the inner end of the port is deleted by half each time each layer is stacked, and the length of the land side chamber 2 or the sea side chamber 6 is increased. When the half of the wave-dissipating block 10 is shortened by half, the edge of the outer sea side or the inner side of the port decreases by one-half of the width of the wave-dissipating block 10 from the lower layer to the upper layer for each block layer. Are stacked in a staircase shape. Further, every time one layer is stacked, one, 1.5, two, etc. are deleted, and the length of the land side room 2 or the sea side room 6 is set to one, 1.5, 2, If it is shortened by one piece, the edges of the outer sea side or the inner side of the harbor will be piled up in a gentle step.

  Therefore, the edge of the wave-blocking block structure 100 or the wave-dissipating block structure 101 is 0.5 pieces, one piece, 1.5 pieces, two pieces, etc. of the wave-dissipating block 10 on the edge each time one layer is stacked. Delete and provide a small stage, or stack several stages vertically, then provide a single stage, and provide a small stage each time a few stages are stacked. be able to.

  The semi-wave-dissipating block 10a may be provided with “cantilever reinforcing side walls 43a” at both ends of the cut surface portion of the semi-wave-dissipating block 10a. The cantilever-reinforced side wall 43a is a piece between the connecting pillar 10g near the two corners of the semi-wave-dissipating block 10a closest to the outer sea side edge or the port-side edge and the cut surface of the semi-wave-dissipating block 10a. The both ends of the semi-wave-dissipating block 10a having a cantilever shape are reinforced. The cantilever reinforcing side wall 43a shares the load from the upper stage with the cantilever reinforcing side wall 43a. The cantilever reinforcing side wall 43a may be provided with a taper made of a vertical surface at a vertical ridge line portion formed by the inner side surface of the cantilever reinforcing side wall 43a and the cut outer sea side edge surface of the semi-quenching block 10a. . This taper alleviates the impact force caused by the waves and also reduces the force that pushes the gap between the wave blocking blocks 1 adjacent to the side. However, the cantilever reinforcing side wall 43a is not provided when the direction of the cut surface of the semi-wave-dissipating block 10a is substantially parallel to the direction from the outside sea side to the inside of the harbor.

  The central connecting column 10g of the half wave-dissipating block 10a is such that the entire central connecting column 10g of the wave-dissipating block 10 has room in the remaining half-wave-dissipating block 10a after the wave-dissipating block 10 is cut in half. It is good also as an aspect which moved to the position which fits in a right angle direction with respect to a cut surface. Further, instead of the cantilever reinforcing side wall 43a, the connecting pillar 10g at the two corners of the semi-wave-dissipating block 10a is moved to the cut surface side so as to share the load from the upper stage part, and the connecting pillar 10g at the central part is moved. May be moved to the coupling surface side of the semi-wave-dissipating block 10a and the wave-dissipating block 10, and in this case, the direction of the cut surface of the semi-wave-dissipating block 10a and the direction from the open sea side toward the inside of the port are generally In the case of being parallel, the connecting pillar 10g at the center of the semi-wave-dissipating block 10a may be omitted. Alternatively, when the half wave-dissipating block 10a is a vertical plane perpendicular to the cut surface and is further cut in half at the center of the cut surface to form a quarter wave block, a quarter wave block is formed. The connecting pillar 10g at the center of the wave-dissipating block is deleted, and the connecting pillar 10g at one corner of the quarter-wave-dissipating block is cut in a direction substantially parallel to the direction from the open sea side toward the inside of the port, or You may move to the corner | angular part which consists of two cut surfaces.

  The size of the wave-blocking block 1 with respect to the land-side room 2, the wave-breaking room 4, and the sea-side room 6 with respect to the wave-dissipating block 10 is one unit of the wave-dissipating block 10, and the land-side room 2 is wave-dissipating. The block 10 is shown as 1.5 units, the wave-breaking chamber 4 including the wave-breaking plate 41 is shown as 1.5 units of the wave-dissipating block 10, and the sea-side chamber 6 is shown as 1.5 units of the wave-dissipating block 10. Regardless of this, the size may be different from this, and the land side room 2 and the sea side room 6 do not have to be the same size, and the number of units of the sea side room 6 is larger than the land side room 2. Good. The size of the wave preventing chamber 4 including the wave preventing plate 41 may be 1.0, 1.5, 2.0, 2.5 units of the wave-dissipating block 10 or the like. The size of the land side room 2 or the sea side room 6 may be different from each other. When the wave-dissipating edge connecting block 12 is used in the land side room 2 or the sea side room 6, 1.5, 2.5, 3.5, 4.5 units, etc. may be used, respectively, and when the wave-dissipating both-edge connecting block 12a is used, 1.0, 2,. It may be 0, 3.0, 4.0 units or the like.

  Although the shape and magnitude | size of the wave-blocking block 1 of this invention are not specifically limited, It will be as follows when an example is shown. The case where the land side chamber 2 and the sea side chamber 6 of the wave-blocking block 1 are comprised with the semi-wave-dissipating block 10a and the wave-dissipating block 10 which makes a square planar shape is shown. The design dimensions of the wave preventing block 1 are such that the dimensions of the rectangular parallelepiped on the outer edge of the wave preventing block 1 are a width of 3.24 m, a length of 14.58 m, and a height of 3.00 m (the height from the upper surface of the upper plate to the lower surface of the lower plate, The height does not include the height of the convex portion.). The manufacturing dimensions of the wave-blocking block 1 are as follows: the width of the rectangular parallelepiped on the outer edge of the wave-blocking block 1 is 3.00 m wide, 13.5 m long, and 3.00 m high (height from the upper surface of the upper plate to the lower surface of the lower plate, The height does not include the height of the convex portion.). Hereinafter, the manufacturing dimensions of the wave-blocking block 1 will be described. The wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f have a thickness of 60 cm, and the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f The plate convex portion 10j and the lower plate convex portion 10k have a planar dimension of 69 cm in length and width, and 34 cm in height, and the upper plate recess 10 m and the lower plate recess 10 m and the lower plate 10 f of the wave block lower plate 10 f. The plate recess 10n has a planar dimension of 162 cm in length and width, and a depth of 36 cm, and the width of the wave-dissipating block 10 constituting the wave-blocking block 1 (the outer periphery of the wave-dissipating block 10 in the concave flat shape) The distance between the outer periphery of the planar shape of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f.) Is 69 cm, which is the same as the length and width of the planar shape of the upper plate convex portion 10j and the lower plate convex portion 10k. The connecting column 10g has a column cross-sectional shape. Octagonal width pillars 70cm to parallel sides forms one another, a length of 180cm, a 60cm thickness of the side wall plate 42 of the breakwater chamber 4, the thickness of the breakwater plate 41 is 60cm.

  The wave-blocking block 1 or the wave-dissipating connection block 11 is a wave-dissipating block upper plate protruding in the vertical direction of the wave-dissipating block 10 incorporated in the land-side room 2 and the sea-side room 6 of the wave-blocking block 1 or the wave-dissipating connection block 11. 10e and the upper plate convex portion 10j and the lower plate convex portion 10k of the wave-dissipating block lower plate 10f, and the wave-dissipating block upper plate 10e and the upper plate concave portion 10m and the lower plate concave portion 10n of the wave-dissipating block lower plate 10f. Since these are fitted in a staggered manner in the vertical direction, a plurality of wave-blocking blocks 1, wave-dissipating connection blocks 11 or wave-dissipating edge connection blocks 12 are stacked in the conventional manner. Compared to the irregular wave-dissipating block, it becomes possible to pile up into a solid and large mass concrete.

  Further, the wave-blocking block 1 or the wave-dissipating connection block 11 is provided on the inner side of the (reverse) square pyramid of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f. Since the taper is formed in the side surface and each side surface of the (reverse) square pyramid shape of the upper plate recess 10m and the lower plate recess 10n of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f, When the taper surfaces are partially caught with each other, the upper plates of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f constituting the land-side chambers 2 and the sea-side chambers 6 of the wave-blocking block 1 or the wave-dissipating connection block 11, respectively. Each of the top 10e and the bottom plate 10f of the wave-dissipating block, such as the wave-blocking block 1, the wave-dissipating connection block 11, or the wave-dissipating edge connection block 12, by the weight of the convex part 10j and the bottom plate convex part 10k. The wave breaker block structure 100 or the wave breaker block 1 or the wave breaker connection block 11 or the wave breaker edge connection block 12 or the like is easily and quickly led to the recess 10m and the lower plate recess 10n. It becomes possible to pile up the wave-dissipating block structure 101 efficiently and firmly.

  A rectangular parallelepiped shape constituting the wave-blocking block 1, the wave-dissipating connection block 11, or the wave-dissipating edge connection block 12, and having the same shape and the same size side surfaces of the wave-dissipating blocks 10 having the same shape and the same size in contact with each other, When the wave-dissipating block 10 is assembled so that the planar outer edges of the four wave-dissipating blocks 10 are similar to the planar shape of the wave-dissipating block 10, the four planar outer edges are formed into a large rectangle. The In the above, the four upper plates are gathered so that the corners of the vertical outer side surfaces of the upper plate projections 10j each having the quadrangular pyramid shape and the square shape of the four wave-dissipating blocks 10 are in contact with each other at one point. The outer edges of the convex portions 10j are assembled so as to be similar to the planar shape of the wave-dissipating block 10, that is, four upper plate convex portions 10j each including one upper plate convex portion 10j of each wave-dissipating block 10. When the outer edges of the planar shape that collects the two are gathered so as to be similar to the planar shape of the wave-dissipating block 10, a large upper plate convex portion is formed. A large rectangular outer edge in which four wave-dissipating blocks 10 are assembled, an outer edge of a large upper plate convex part in which four upper plate convex parts 10j are gathered, and a large outer edge of the four wave-dissipating blocks 10 The edges of one wave-dissipating block 10 in which one wave-dissipating block 10 is superimposed on the upper layer of the central part are parallel to each other so that their short sides and their long sides are in the same direction. These outer edges are arranged side by side so as to be similar to the planar shape of the wave-dissipating block 10. When one wave-dissipating block 10 is overlaid on the upper layer of the central portion of the large outer edge where the four wave-dissipating blocks 10 are arranged, the four wave-dissipating blocks 10 arranged in the lower layer are formed in the center of the planar shape. A large upper plate protrusion fits into the lower plate recess 10n of the upper wave-dissipating block lower plate 10f, and each of the four protruding from the four corners of the upper wave-dissipating block lower plate 10f. The lower plate convex portion 10k is inserted into a part of each of the four upper plate concave portions 10m of the respective wave-dissipating block upper plate 10e of the four wave-dissipating blocks 10 in the lower layer, and each wave-dissipating block 10 is In this way, they are firmly fitted in a staggered manner in the vertical direction, and in this way, the land side room 2 and the sea side room 6 such as the wave-blocking block 1, the wave-dissipating connection block 11, or the wave-dissipating edge connection block 12. Is equipped with a wave-dissipating block 10 From the above, the convex portion and the concave portion of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f can be fitted to each other in a vertical direction in a staggered manner. 11 or the wave-dissipating edge connecting blocks 12 can be stacked to form a solid wave-breaking block structure 100 or wave-dissipating block structure 101.

  10 and FIG. 11, a wave-dissipating block 10 includes a wave-dissipating block upper plate 10e and a wave-dissipating block lower plate 10f, and a plurality of connecting columns 10g that couple the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f. And have. The wave-dissipating blocks 10 constituting the land-side chamber 2 and the sea-side chamber 6 of the wave-blocking block 1 or the wave-dissipating connection block 11 are each a rectangular parallelepiped having the same shape and the same dimensions. The wave-dissipating block upper plate 10e has a side surface formed in a vertical plane, a planar shape formed in a rectangular shape, and a rectangular pyramid shape that protrudes upward at the four corners of the upper surface, and the planar shape is a rectangular upper plate. A convex portion 10j is formed, and an upper plate concave portion 10m having an inverted quadrangular pyramid shape that is depressed downward in the central portion of the upper surface and a square shape is formed. The wave-dissipating block lower plate 10f has a side surface formed in a vertical plane, a planar shape formed in a rectangular shape, and an inverted quadrangular truncated pyramid that protrudes downward at the four corners of the lower surface. A plate convex portion 10k is formed, and a lower plate concave portion 10n having a quadrangular pyramid shape that is recessed upward in the center of the lower surface and a square shape is formed. The wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are vertically symmetrical with the same thickness, the planar shapes are the same and have the same dimensions, and the upper and lower surfaces are parallel to each other. The top surface of 10e and the bottom surface of the bottom plate 10f of the wave-dissipating block are the top surface of the top plate convex portion 10j of the top plate 10e and the bottom surface of the top plate concave portion 10m, and the bottom plate convex portion 10k of the bottom plate 10f of the wave-dissipating block. The lower surface and the upper surface of the lower plate recess 10n are formed in parallel with each other and horizontally, and the side surfaces of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f form a common vertical plane that faces the same direction.

  10 and FIG. 11, a wave-dissipating block 10 includes a wave-dissipating block upper plate 10e and a wave-dissipating block lower plate 10f, and a plurality of connecting pillars that couple the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f. 10g, and a plurality of connecting pillars 10g of each wave-dissipating block 10 connect the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f at five locations at the four corners and the central part. Are formed in a rectangular parallelepiped outline.

  The upper plate convex portion 10j and the lower plate convex portion 10k of the wave-dissipating block 10 shown in FIGS. 10 and 11 are both the same shape or the same shape that is upside down and the same height and size, and the planar shape is The flat shape of the wave-dissipating block 10 is similar, and the upper plate concave portion 10m and the lower plate concave portion 10n have the same shape upside down and the same height and the same size. And similar shape.

  10 and FIG. 11, the short and long sides of the planar shape of the upper surface of the wave-dissipating block upper plate 10e and the lower surface of the wave-dissipating block lower plate 10f, and the upper plate protrusions on the upper surface of the wave-dissipating block upper plate 10e. 10 j, the upper plate concave portion 10 m and the lower plate convex portion 10 k on the lower surface of the wave-dissipating block lower plate 10 f and the short side and the long side of each planar shape of the lower plate concave portion 10 n are the short sides and the long sides of each other. They are parallel lines that point in the same direction.

  The two outer surfaces of the upper plate convex portion 10j of the wave-dissipating block 10 shown in FIG. 10 and FIG. The upper plate 10e forms two vertical planes extending from the two side surfaces, respectively, and the same vertical plane facing the same direction. The side surface has the same direction as each of the two vertical planes extending from the two side surfaces of the wave-dissipating block lower plate 10f sandwiching the corner portion having the lower plate convex portion 10k of the wave-dissipating block lower plate 10f. Make the same vertical plane facing.

  The upper plate concave portion 10m and the lower plate convex portion 10k of the wave-dissipating block 10 shown in FIGS. 10 and 11 have four wave-dissipating blocks 10 of the same type and the same size so that side surfaces of the same shape are in contact with each other. The outer edges of the planar shape of the wave-dissipating block 10 are gathered so as to be similar to the planar shape of the wave-dissipating block 10, and four lower plate convex portions 10k are respectively provided at the center of the lower plate convex portions 10k. Are arranged so that the outer corners thereof are substantially in contact with each other, and are assembled so as to be similar to the planar shape of the wave-dissipating block 10, that is, each of the four lower plate protrusions 10 k of each wave-dissipating block 10. When the outer edges of the planar shape in which the lower plate convex portions 10k are assembled are gathered so as to be similar to the planar shape of the wave-dissipating block 10, the upper plate of the lower wave-dissipating block 10 adjacent to the large lower-plate convex portion It is formed so that it can be fitted into the recess 10m, The lower plate concave portion 10n and the upper plate convex portion 10j of the cup 10 have four wave-dissipating blocks 10 of the same type and the same size so that side surfaces of the same type and the same size are in contact with each other. Are assembled so that their outer edges are similar to the planar shape of the wave-dissipating block 10, and the four upper plate projections 10j are respectively in contact with the central portion of each of the upper plate projections 10j. Are arranged so as to be similar to the planar shape of the wave-dissipating block 10, that is, four upper-plate convex parts 10 j each consisting of one of the upper-plate convex parts 10 j of each wave-dissipating block 10 are collected. When the outer edges of the flat surfaces thus formed are gathered so as to be similar to the planar shape of the wave-dissipating block 10, a large upper plate convex portion is formed so that it can be fitted into the lower plate concave portion 10n of the adjacent upper wave-dissipating block 10 Is done.

  10 and 11, the wave-dissipating block 10 includes a horizontal wave-dissipating block upper plate 10 e and a wave-dissipating block lower plate 10 f, and a wave-dissipating block upper plate 10 e and a wave-dissipating block lower plate 10 f in the vertical direction. It is composed of a plurality of connecting pillars 10g, and in addition to the four corners of the wave-dissipating block 10, a vertical connecting pillar 10g is provided in the central part. Early intermittent flow similar to the wave of waves in the waves of the waves, broken by the upper plate 10e and the wave-dissipating block lower plate 10f (horizontal reciprocating water flow, the flow from the open sea side is a large force of fast flow However, it is possible to generate a large number of vortices in the flow as shown in FIG. The vertical connecting pillar 10g in the substantially central portion of the wave-dissipating block 10 and the four vertical connecting pillars 10g near the four corners are combined to generate an intermittent flow of the wave that breaks through the wave-disconnecting block 10. Such a fast flow can be greatly increased by the large action of the vertical connecting pillar 10g mainly in the center, greatly increasing the amount of vortices generated and greatly increasing the wave energy derating rate. It becomes possible to make it. The wave-dissipating block 10 is an underwater cave comprising a horizontal wave-dissipating block upper plate 10e and a horizontal wave-dissipating block lower plate 10f, and a plurality of vertical connecting columns 10g that connect these upper and lower plates. It has the shape of a fish and has a reef effect as an underwater cave.

  The wave-dissipating connection block 11 shown in FIG. 12 has two or more and the same number of wave-dissipating blocks 10 of the same type and the same size adjacent to each other, and is connected in a straight rectangular parallelepiped shape with side surfaces of the same type and the same size in common. Thus, the “wave-dissipating connection block 11” is formed. The wave-dissipating connection block 11 has a transmission-type connection block structure in which only the wave-dissipating blocks 10 are connected.

  As shown in FIG. 13, the decoupling edge connection block 12 in which the semi-quenching block 10 a is deleted from one end portion of the decoupling connection block 11, At the center of the wave-dissipating block 10, the wave-dissipating block 10 is cut in half at the center of the wave-dissipating block 10 at the center of the long-axis direction of the connecting block 11, and the remaining part of the wave-dissipating connecting block 11 is removed. The portion is defined as a “wave-dissipating edge connecting block 12” having a rectangular parallelepiped shape. The same type and the same dimension of the extinguishing edge connecting block 12 shown in FIG. 13 is set so that the central axis in the major axis direction of the extinguishing edge connecting block 12 is parallel to the direction from the open sea side to the inner side of the port. The semi-wave-dissipating blocks 10a at the ends of the wave-edge connecting blocks 12 are adjacent to each other to form a first block layer. The semi-wave-dissipating block 10a at the end of the wave-dissipating edge connecting block 12 of the same type and the same size as the first block layer faces the opposite side of the first block layer, and the semi-wave-dissipating block 10a at the end and both ends The parts are aligned and the number sequence is arranged in a rectangular shape to form a second block layer. The central axis of the long axis direction of one row of the second block layer is placed on the upper layer of the contact portion that is the center of the two rows of the first block layer, and the ends are aligned and the inner side of the harbor from the outside sea side. If the upper and lower wave-dissipating blocks 10 are stacked in parallel with each other in a zigzag pattern, the outer sea side surface and the outer edge of the inner port surface of the stacked wave-dissipating edge connecting block 12 are the same vertical plane. It can be piled up in the mode which makes.

  In another embodiment, the wave-removing edge connecting block 12 a obtained by deleting the half-wave-dissipating block 10 a from both ends of the wave-dissipating connecting block 11 is the wave-dissipating block 10 at both ends of the wave-dissipating connecting block 11. Is cut in half in the vertical plane perpendicular to the central axis in the major axis direction of the wave-dissipating connecting block 11 and at the center of the wave-dissipating block 10, The remaining part of the wave-dissipating connection block 11 from which the cut pieces have been removed is referred to as a straight rectangular parallelepiped-shaped "wave-dissipating both-edge connecting block 12a". The half-wave-dissipating blocks 10a at both ends of the wave-dissipating both-edge connecting block 12a, with the long-axis central axis parallel to the direction from the open sea side to the harbor inside. Are arranged adjacent to each other, aligned at both ends, and arranged in a rectangular shape to form a first block layer, and on the upper layer adjacent to the first block layer, the connection block 12a for both sides of the first block layer and the rectangular parallelepiped The outer edge contour of the shape has the same shape and the same size, and the same number of wave-dissipating blocks 10 and the outer edge contour of the same shape and the same size are arranged in the first block layer on the first block layer. Are arranged in a rectangular shape adjacent to each other in parallel to form a second block layer. The center axis of one row of the second block layer is placed on the upper layer of the contact portion that is the center of the two rows of the first block layer, and the ends are aligned and parallel to the direction from the outside sea side to the inside of the port If the upper and lower wave-dissipating blocks 10 are stacked in a zigzag pattern, the outer sea side surface at the end of the wave-dissipating both edges connecting block 12 and the outer edge of the wave-disconnecting block 11 and the outer edge of the inner side surface of the port are the same. It can be stacked to form a vertical plane. Moreover, the wave-dissipating connection block 11 may be used for the first block layer, and the wave-dissipating both-edge connecting block 12a may be used for the second block layer.

  The wave-dissipating connection block 11 is configured so that both ends of the wave-dissipating connection block 11 of the same type and the same size are aligned and the central axis in the major axis direction of the wave-dissipating connection block 11 is parallel to each other. A flat rectangular parallelepiped-shaped "wave-dissipating block array 11a" in which two rows to integer columns are connected in a direction perpendicular to the central axis in the major axis direction, and one end row of the wave-dissipating block block 11a is defined as an end The “wave-dissipating edge connecting block row having a flat rectangular parallelepiped shape having 1.5 to an integer row minus 0.5 rows of wave-dissipating connecting blocks 11 having a shape vertically cut along the central axis in the long axis direction of the row. As shown in FIG. 13, the wave-dissipating edge connection block 12 or the wave-dissipating edge connection block array body 12 b shown in FIG. 13 is configured such that one of the end rows includes the semi-wave-dissipating block 10 a. Outside the mass concrete structure Disposed to so as to be in contact with, used for edge of the mass concrete structures such as breakwaters and wave-absorbing ridge may be stacking the edge in a vertical plane.

  The wave-dissipating edge connecting block array 12b has two types of symmetry, depending on the difference in shape depending on whether the wave-dissipating connecting block 11 on the left or right side of the wave-disconnecting connecting block array 11a is cut in half. Exists. In addition, the end row is vertically cut in half along the central axis in the major axis direction of the end row of the row that is perpendicular to the edge made of the semi-wave-dissipating block 10a of the connecting block row 12b for the wave-dissipating edge. A flat rectangular parallelepiped shape "disconnection corner portion connection block array 12c" having a shape from which the cut pieces are removed, and the extinction angle portion connection block array 12c has two edges that are perpendicular to each other. It is composed of a semi-wave-dissipating block 10a and is arranged so that the cut surface of the semi-wave-dissipating block 10a is in contact with two outer edges of the mass-concrete structure, and is used at the corner of the mass-concrete structure.

  14 to 17, the side surfaces of the same type and the same size of the wave blocks 1 of the same type and the same size are arranged so that the central axes in the major axis direction of the plurality of wave blocks 1 are parallel to each other. Are formed so as to be in contact with each other so that both end portions are aligned and two to integer rows are aligned and connected to form a “breakwater block array 1a”. As shown in FIGS. 14 and 15 in the first embodiment of FIGS. 2 and 3, and in the second embodiment of FIGS. 4 and 5, the wavebreak block 1 is as shown in FIGS. 16 and 17. In addition, the end row of the wave-blocking block row 1a is formed into a shape cut vertically by the central axis in the major axis direction of the end row parallel to the coupling surface of the row, and the 1.5 row to the integer row minus 0.5 A “breakproof edge block array 1b” is formed. As shown in FIG. 9, the block array 1 b for the breakwater edges is such that the cut surfaces of the half rows obtained by cutting the breakwater blocks 1 along the central axis in the major axis direction are in contact with the edges of the breakwater block structure 100. It is arranged and used for the edge that is parallel to the direction from the open sea to the harbor, and the edge that is parallel to the direction from the open sea side to the inner side of the wave blocking structure 100 is constructed in a vertical plane. Can do.

  14 and FIG. 15 shows a block array 1b for a wave-breaking edge in the first embodiment of the wave-blocking block 1 shown in FIG. 2 and FIG. The right end row is formed into a shape that is vertically cut by the central axis in the major axis direction of the end row parallel to the connecting surface of the row, and is a row row block body 1b of 1.5 rows of breakwaters, 15 is used on the edge parallel to the direction from the open sea side to the harbor inside of the right side wave blocking block structure 100, and FIG. 15 shows the left end row of the two row wave blocking block rows 1a as the row coupling surface. Is a block array 1b for a wave-proof edge of 1.5 rows, which is formed by cutting vertically at the central axis in the major axis direction of the end row parallel to the left-side wave-proof block structure as viewed from the open sea side Used on the edge of the body 100 parallel to the direction from the outside sea side to the harbor inside. 14 and 15, it is possible to construct an edge that is parallel to the direction from the outer sea side to the inner side of the harbor of the wave blocking block structure 100 in a vertical planar shape.

  16 and FIG. 17 is a block array body 1b for a wave-breaking edge, in the second embodiment of the wave-blocking block 1 shown in FIG. 4 and FIG. The right end row is formed into a shape that is vertically cut by the central axis in the major axis direction of the end row parallel to the connecting surface of the row, and is a row row block body 1b of 1.5 rows of breakwaters, 17 is used for the edge parallel to the direction from the open sea side to the harbor inside of the right side wave blocking block structure 100 as viewed from the side, and FIG. Is a block array 1b for a wave-proof edge of 1.5 rows, which is formed by cutting vertically at the central axis in the major axis direction of the end row parallel to the left-side wave-proof block structure as viewed from the open sea side Used on the edge of the body 100 parallel to the direction from the outside sea side to the harbor inside. 16 and 17, an edge that is parallel to the direction from the outer sea side to the inner side of the harbor of the breakwater block structure 100 can be constructed in a vertical planar shape.

  As shown in FIGS. 14 to 17, the wave blocking blocks 1 of the wave blocking edge block array 1 b are cut in half, and the wave blocking chamber 4 is cut in half along the central axis in the major axis direction of the wave blocking block 1. In addition, the side wall plate 42 and the wave plate haunch portion, and the side wall plate reinforcing side wall 43b and the wave preventing plate reinforcing side wall 43 in the breaker chamber 4 in the remaining piece are cut in parallel to the central axis of the wave blocking block 1. You may make it move to a cut surface side so that it may become a left-right symmetric shape with respect to the center axis line in a piece. In this case, the side wall plate 42, the haunch portion of the wave-breaking plate, the side wall plate reinforcing side wall 43b, and the wave-proofing wave, which are provided at the original positions of the remaining cut piece portion of the wave-breaking block 1 cut in half. The plate reinforcing side wall 43 is moved and deleted from the original place, and the fish through hole 41a cut in half is also deleted. Further, the connecting pillars 10g at both ends of the semi-wave-dissipating block 10a in which the cut surface of the semi-wave-dissipating block 10a is parallel to the direction from the open sea side toward the inside of the harbor are moved to the cut-surface side, 10g may be deleted.

  FIG. 18 shows the details of an aspect in which the wave blocking block 1 of the first embodiment shown in FIGS. 2 and 3 and the wave blocking block 1 of the second embodiment shown in FIGS. 4 and 5 are stacked. The upper layer shown on the left side of the figure is the wave blocking block 1 of the first embodiment, the lower layer shown on the right side is the wave blocking block 1 of the second embodiment, the upper side of the figure is the port inner side, and the lower side is the open sea side It is. The wave-dissipating blocks 10 incorporated in the land-side chamber 2 and the sea-side chamber 6 of the wave-blocking block 1 are arranged in a staggered manner in the front and rear, right and left in the lower layer and the upper layer, and the convex and concave portions of the wave-dissipating block 10 A firm wave-blocking block structure 100 in which the wave-blocking blocks 1 are stacked can be constructed by tightly fitting each other in a zigzag manner.

  As shown in FIG. 18, the wave-blocking block structure 100 has the wave-dissipating block 10 incorporated in the sea-side chamber 6 of the wave-blocking block 1, so the sea-side chamber 6 also has a transmission type wave-dissipating function. It becomes a structure. Waves collide with the wave-blocking block structure 100 constructed by stacking the wave-blocking blocks 1 in a zigzag pattern, so that the horizontal plate composed of the wave-dissipating block lower plate 10f and the wave-dissipating block upper plate 10e in the seaside chamber 6 Waves from the open sea are broken by the layers and floors. As shown in FIGS. 18 and 19, the breakwater block structure 100 has a fast intermittent flow (horizontal flow) in which the energy of the waves broken inside the seaside chamber 6 of the breakwater block 1 resembles a stepped wave of a river flow. When the water passes in the direction of the reciprocating water flow in the direction), a vortex is generated by the vertical connecting column 10g of the sea side chamber 6 to reduce the wave energy. The wave-dissipating block 10 incorporated in the sea side chamber 6 is provided with a connecting pillar 10g in the central part in addition to the connecting pillars 10g at the four corners, so that vortices can be generated in the central part of the wave-dissipating block 10 as well. Can be generated. By having one connecting column 10g in the central portion of the wave-dissipating block 10, the amount of vortices generated by greatly disturbing the flow such as a fast intermittent flow of wave breaking waves passing through the inside of the seaside chamber 6 can be reduced. It can be greatly increased, and the rate of deactivation of fast flow such as intermittent flow can be greatly increased. Further, a fast flow such as this intermittent flow collides with the wave preventing plate 41 and is diffused in the vertical direction in the wave preventing chamber 4, and the wave splash that jumps upward is reduced by the side wall plate 42 arranged in a staggered manner. As a result, the jumping height is reduced, the proportion of waves splashing inside the harbor can be reduced, and the waves in the harbor can be made calm. Since the sea-side chamber 6 also has a wave-dissipating function, the wave-breaking block structure 100 eliminates the need for stacking conventional shaped wave-dissipating blocks on the front side of the seawater side of the breakwater, greatly increasing the cost. Savings are possible.

  As shown in FIG. 19, the wave-blocking block structure 100 and the wave-breaking block structure 101 are formed as a wave-blocking block structure 100 using the wave-blocking block 1 having an impermeable connection block structure in the middle layer portion and the upper layer portion. It is possible to secure the calmness of the harbor by reducing the wave height transmission rate to the harbor for waves in the open sea. In addition, the wave-dissipating block structure 101 including the wave-dissipating edge connecting block 12 having a transmission-type connecting block structure in the lower layer is used to communicate between the sea water in the harbor and the open sea, and the sea water in the harbor and the sea water in the open sea are exchanged. It is possible to improve the water quality in the port, secure a fish passage through which fish can freely pass between the open sea and the port, and have a fish reef effect as an underwater cave.

  As shown in FIG. 19, the method of stacking the breakwater block 1 and the breaker edge connection block 12 uses a plurality of breakwater blocks 1 having an impermeable connection block structure in the middle layer portion and the upper layer portion. A plurality of wave-dissipating edge connection blocks 12 having a transmission-type connection block structure are used in the lower layer portion of the breakwater. As a result, the wave-blocking block 1 and the wave-dissipating edge connecting block 12 are stacked using the wave-blocking block 1 having a non-transparent connection block structure in the upper layer and the middle layer near the sea surface. At a position deeper than a quarter of the wavelength of the wave of interest from the sea surface with a small effect, using the wave-dissipating edge connection block 12 and the wave-dissipating connection block 11 of the transmission-type connection block structure, A breakwater composed of the breakwater block structure 100 and the underlying wavebreak block structure 101 can be constructed. Regarding the wave-dissipating edge connection block 12 and the wave-dissipating connection block 11 of the transmissive connection block structure used for the lower layer, the depth of the breakwater is deep, the height of the breakwater is increased, and the width of the lower layer of the breakwater If the length of the block of the transmissive connection block structure used for the lower layer becomes longer, the block of the lower layer part is divided into a connection block 12 for the extinction edge and several wave-dissipation connection blocks 11. It may be used.

  As shown in FIG. 19, at the boundary between the wave-dissipating edge connection block 12 of the transmission type connection block structure used for the lower layer part and the wave blocking block 1 of the non-transmission type connection block structure used for the middle layer part, Inside the wave-breaking chamber 4 including the wave-blocking plate 41 of the wave-blocking block 1 that forms the lowermost layer of the middle layer, the wave-dissipating block lower plate 10f (connection column) is used instead of the side wall plate 42 and the lower portion of the wave-blocking plate 41. 10g may be deleted and replaced with a lower plate convex portion 10k protruding downward from the wave-dissipating block lower plate 10f and a lower plate concave portion 10n recessed upward from the central portion of the wave-dissipating block lower plate 10f. Alternatively, if the above replacement is not performed, the uppermost layer of the lower layer adjacent to the lower portion of the wavebreaking chamber 4 including the wavebreaking plate 41 of the wavebreaking block 1 constituting the lowermost layer of the middle layer is erased. You may delete the upper board convex part 10j which protrudes upwards from the wave-dissipating block upper board 10e which comprises the connection block 12 for wave edges. When replacing with the lower part of the side wall plate 42 and the wave-breaking plate 41 with the wave-dissipating block lower plate 10f, the inner side surface of the side-wall plate 42 and the outer sea side surface of the wave-breaking plate 41 and the upper surface of the wave-dissipating block lower plate 10f A corner portion formed may be reinforced by providing a haunch portion.

  The weight block 14 is a flat weight block 14 in which all the connecting pillars 10g of the wave-dissipating block 10 are deleted and the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f are integrally coupled. Formed. Similar to the wave-dissipating block 10, the weight block 14 can be used by stacking the weight blocks 14 firmly in a staggered manner in the vertical direction.

  The weight block 14 is connected to the top end of the wave-blocking block structure 100 or the wave-dissipating block structure 101, such as the wave-blocking block 1 or the wave-dissipating connection block 11 in the uppermost layer in order to improve the stability. In addition to being able to be used as heavy concrete, as a foundation block at the bottom of the lowermost layer of the wave-blocking block structure 100 or the wave-dissipating block structure 101, or the top-end protection work at the top of the foundation mound, the slope method It can be used as a surface protector or a cover. In addition, in order to prevent the scouring of the lake bottom and the riverbed and to stabilize the structure, it can be used as a revetment or a dam consolidation work or a floor protection work. Moreover, the weight block 14 can also be used as a retaining wall for the earth wall, a slope protection work for the embankment surface or the cut surface, and the like.

  Moreover, since the weight block 14 fits firmly in a zigzag shape up and down by using the weight block 14 over two or more stages as a rooting work or a floor protection work, a connecting bar or a connecting chain Even if the weight blocks 14 are not connected and fixed to each other using the like, the weight block 14 can be easily prevented from moving. Further, when the weight block 14 is used as the topmost top end of the wave-blocking block structure 100, if the weight of the weight block 14 as the top end weight concrete is insufficient, it can be easily stacked. .

  Further, in the same manner as the wave-dissipating block 10, the weight block 14 may connect a plurality of weight blocks 14 to form a weight-connected block 14 a having a rectangular planar shape connected in a straight line. it can. Further, the weight blocks 14 may be connected to each other and integrated to form a weight-connected block array with improved stability, and the wave-proof block structure 100 or the wave-dissipating block structure 101 may be used. On the edge of the uppermost layer, the overlapping edge connecting block 14b having the same planar shape as the wave-dissipating edge connecting block 12, the wave-dissipating edge connecting block array 12b, or the wave-dissipating-angle connecting block array 12c is provided. Alternatively, the overlapping edge connecting block array and the overlapping corner connecting block array 14c may be used. However, the weight block 14 is not stacked on the upper portion of the wave preventing chamber 4 including the wave preventing plate 41 having a space penetrating in the vertical direction of the uppermost wave preventing block 1.

  In addition, the weight block 14 is used as a top end layer block of each uppermost layer, such as the wave-blocking block structure 100 and the wave-dissipating block structure 101, the retaining wall work, the root hardening work, the floor protection work, and the slope protection work. The uppermost weight of the lowermost block 14 and / or the lowermost layer weight when used as a lower basic block of the lowermost layer such as the wave-blocking block structure 100 or the wave-dissipating block structure 101 You may abbreviate | omit the protrusion part which protrudes from the lower surface of the block 14 below. In addition, when the weight block 14 is used as a basic block such as the wave-blocking block structure 100 and the wave-dissipating block structure 101, the bottom surface of the weight block 14 is formed of a cobblestone-like protrusion protruding downward. The unevenness may be arranged on the entire surface or a part thereof.

  When the planar shape of the wave-dissipating block 10 is a rectangle, there are long sides and short sides, the direction of the wave-dissipating block 10 is generated, and the same number of wave-dissipating blocks 10 of the same type and the same size are used depending on the direction in which the wave-dissipating block 10 is used. Two types of planar shapes such as the wave-blocking block structure 100 or the wave-dissipating block structure 101 used are generated, but the planar shape of the wave-dissipating block 10 is used in a square shape so that the directionality of the wave-dissipating block 10 does not occur. May be.

  If the wave-dissipating block 10 is manufactured in the same shape and the same size symmetrical with respect to a horizontal plane or a vertical plane passing through each central axis in the vertical and horizontal directions, the steel mold frame for manufacturing the wave-dissipating block 10 Most of the mold pieces used can be made common. As a result, the wave-dissipating block 10 can efficiently use mold pieces, reduce the number of expensive molds for producing steel molds to a small quantity, and is easily and economically excellent. Each concrete member can be manufactured.

  The wave-blocking block 1 and the wave-dissipating block 10 may be chamfered (not shown) in each concrete member, or may be provided with reinforcing bars (not shown) inside each concrete member. The reinforcing bar may be any material as long as it is resistant to corrosion, has a high tensile strength, and has a high durability. However, when steel is used, it is subjected to anticorrosion treatment such as painting or plating. It is desirable that

  The wave-blocking block 1 and the wave-dissipating block 10 are not the site where quality control of each concrete member is difficult to perform, but in the PC factory where quality control is perfect, the wave-dissipating block upper plate 10e, the wave-dissipating block lower plate 10f, the connecting pillar It may be divided into 10 g, a wave prevention plate 41, a side wall plate 42, etc., manufactured with high strength and high quality, and each of these concrete members may be transported to the site and assembled on site. Each concrete member has a specific gravity of about 2.7 to 3.0 by using electric furnace oxidation slag or copper slag having a high specific gravity for the concrete aggregate when it is assumed to be manufactured in a PC factory or the like. It may be manufactured using high specific gravity concrete. There are also limited ports where caisson production yards exist to build caisson similar to shipbuilding docks. However, the wave-blocking block 1 or the wave-dissipating connection block 11 or the like can be connected to the wave-blocking block 1 or the wave-dissipating block 11 or the like as long as a square can be secured in the vicinity of the construction site or in a nearby fishing port. It can be assembled into a block 11 or the like.

  In order to improve the stability of the wave-blocking block structure 100 or the wave-dissipating block structure 101 shown in FIG. 1, FIG. 9, and FIG. 19, each concrete member increases the specific gravity of the concrete to increase the weight in water. The wave-blocking block 1 and the wave-dissipating block 10 may be used, and some or all of the concrete coarse aggregate contains a large amount of iron, but is currently treated as waste. It may be one that uses the generated electric furnace oxidation slag and / or one that uses copper slag that is generated during refining of copper in part or all of the concrete fine aggregate. By blending electric furnace oxidation slag as coarse aggregate and / or copper slag as fine aggregate, the specific gravity of the concrete itself is increased, and the wave-blocking block structure 100 or the wave-dissipating block It is possible to improve the stability of Zotai 101. By increasing the specific gravity of the wave-blocking block structure 100 or the wave-dissipating block structure 101, the stability in water can be greatly increased, and the stability in general concrete products and in water is the same. In this case, the cross-sectional area can be reduced, and the design and construction costs can be reduced.

  In order to improve the stability of the wave-blocking block structure 100 or the wave-breaking block structure 101, the specific gravity of the concrete used for manufacturing the wave-blocking block 1 or the wave-breaking connection block 11 is increased, and the wave-breaking The size per block 10 may be increased to increase the weight per wave-dissipating block 10. In addition, since the wave-dissipating block 10 is incorporated in the land-side room 2 and the sea-side room 6 of the wave-blocking block 1 or the wave-dissipating connection block 11, one wave-breaking block can be obtained by increasing the weight of the wave-dissipating block 10. The weight of one unit of one or the wave-dissipating connection block 11 can be increased. Further, side surfaces of the same type and the same size of a plurality of wave-dissipating blocks 10 of the same type and the same size are connected in common and connected to a straight rectangular parallelepiped shape so that the central axis in the major axis direction is parallel to the port direction from the open sea. Thus, the row of the wave-blocking block 1 or the wave-dissipating connection block 11 is arranged so that the energy received from the waves in the open sea is substantially minimized. Further, the upper plate convex portion 10j of the wave-dissipating block upper plate 10e and the wave-dissipating block lower plate 10f constituting the upper and lower plates of the land-side chamber 2 and the sea-side chamber 6 of the wave-blocking block 1 or the wave-dissipating connecting block 11, and The lower plate convex portion 10k, the upper plate concave portion 10m, and the lower plate concave portion 10n can be firmly fitted in the vertical direction in a staggered manner in the vertical direction. By these, the wave-blocking block structure 100 or the wave-breaking block structure 101 can resist rough waves from the open sea, can be made difficult to move by the force of waves, and the wave-blocking block 1 or It is possible to prevent the wave-dissipating connection block 11 from moving, and it is also possible to prevent the plurality of wave-blocking blocks 1 or the wave-dissipating connection blocks 11 from repeatedly colliding with each other due to waves and causing the concrete to be fatigued. It becomes.

  In the present application, the wave-blocking block 1 or the wave-dissipating connecting block 11 may not be manufactured with strictly accurate dimensions and shapes as long as there is no hindrance to the use in civil engineering work. When the respective side surfaces of the wave-blocking block 1 or the wave-dissipating connection block 11 are brought into contact with each other, the side surfaces may not be completely in contact with each other but may be in a state of being in general contact.

  In the present application, terms indicating shapes such as “cuboid”, “square”, “rectangle”, “octagon”, “circular”, “ellipse” and “similarity”, “parallel”, “horizontal” , “Vertical”, “same”, “adjacent” and “center” are not only the exact meanings of these terms, but also as long as they do not hinder their use in civil engineering work. It is used as a term including the case of a simple shape or the case where it is roughly such a position.

  In the present application, the shape of the upper plate convex portion 10j and the lower plate concave portion 10n of the wave-dissipating block 10 is defined as a square pyramid, and the shape of the lower plate convex portion 10k and the upper plate concave portion 10m is defined as an inverted square pyramid. In an aspect having a notch surface or a haunch surface in which the corners of the inner surface and the outer surface are notched with a straight line or a curve, if the notched or haunched portion is counted as one side (reverse), a pentagonal frustum or (reverse) ) Hexagonal frustum or (reverse) octagonal frustum. In addition, an aspect having a notch surface or a haunch surface notched by a curve cannot be strictly called a truncated pyramid. However, in the present specification, the upper plate convex portion 10j and the lower plate convex portion 10k. As for the names of the shapes of the upper plate recess 10m and the lower plate recess 10n, a notch surface or a haunch surface that can be said to be a kind of wide “chamfering” is not counted as one side, but a square frustum or an inverted square pyramid. It is called a table.

  20 and FIG. 21, the construction method of the wave-blocking block structure 100 includes a wave-blocking block 1, a wave-dissipating block 10, a wave-dissipating connection block 11, a wave-dissipating connection block array 11a, and a wave-dissipating edge. Transport the connecting block 12, the wave-blocking block array 1a, the wave-blocking edge block array 1b or the weight block 14 (hereinafter referred to as "wave-blocking blocks") from the block yard to the installation site, It is installed at a predetermined location.

  The construction method of the wave-blocking block structure 100 shown in FIG. 20 and FIG. 21 is the first embodiment, as shown in FIG. 20 and FIG. A wave-blocking block or the like is placed on a horizontal girder 83 that can be set and removed from a trolley opening 81 of a wide trolley 80 provided with a section 81. Tow to a predetermined installation place in a state of being tightly coupled to the trolley 80 with a fiber rope, a fiber band, a wire rope, a chain, etc. Then, it is hung on a carriage 80 or a catamaran and transported to a predetermined installation location. In this trolley 80, several towers 82 of the same height and low level are attached to the both sides of the pier opening 81 along the edge of the pier opening 81, and the upper part of the tower 82 on each side is horizontal. A plurality of large hoist cranes 86 are attached to a traveling beam 85 that is connected by a cross beam 83 and is suspended from the upper cross beam 83 via a plurality of large hinges 84. The carriage 80 is not limited to this, and several jib cranes may be attached.

  The construction method of the wave-blocking block structure 100 shown in FIG. 20 and FIG. 21 is that when installing the wave-blocking block 1 at a predetermined location, as shown in FIG. A plurality of platforms on which a wave-breaking block or the like is suspended from 80 vertically long pier openings 81 using several large hoist cranes 86 or several jib cranes, or several jib cranes are attached. It is suspended between a ship 80 or a catamaran with a wavebreak block or the like sandwiched between them and installed at a predetermined location. The construction method of the breakwater block structure 100 includes an anchor (not shown), a anchor for anchoring a ship, a chain, a wire rope, a lever block (registered trademark), a winch, etc. A wave-blocking block or the like is installed at a predetermined installation location while being finely adjusted using a “winch or the like”).

  In addition, the construction method of the wave-blocking block structure 100 shown in FIG. 22 is an air bag 70 or an air bag or a float in which a plurality of divided air chambers 71 are formed in a transportation process. You may attach to the upper part and the lower part of the wave-dissipating block upper board 10e which comprises the side and side wall board 42, and the upper board of the land side room 2 and the sea side room 6, and a valve is provided in each air chamber 71 at this time. It is attached and inflated by sending air to the air bag 70 and the air bag, or by replacing the water in the air with air or attaching a float (hereinafter referred to as “operation of air bag etc.”). It is also possible to reduce the weight of the water underwater and float up to near the sea surface.

  The material of the air bag 70 shown in FIG. 22 is a material that can withstand the load from the wavebreaking block and the like, and is difficult to tear and torn, and can be easily and safely attached to and removed from the wavebreaking block. Any material may be used as long as it is. The mounting material for mounting the air bag 70 to a wave-blocking block or the like includes a steel plate, a chain, a wire rope, a metal band, a fiber band, a fiber rope, a porous metal plate, a porous plastic plate, a net, a sheet, etc. In addition, a material and a shape that are less likely to damage the wave-blocking block or the like may be used. The air bag 70 can be attached by any attachment method as long as the attachment work and the removal work to the wavebreak block and the like can be safely performed and the transportation installation work can be safely performed.

  The construction method of the breakwater block structure 100 shown in FIG. 20 and FIG. 21 performs operations such as hoist type crane operation of the carrier ship 80, jib crane operation of the crane ship, winch and the like in the installation process. The operation of the valves of the plurality of air chambers 71 shown in FIG. In the installation process, when the air bag 70, the air bag or the float is used, the air bag 70 or the valve of the air bag is operated so that the air bag 70 is deflated, or air and water are replaced, or the air bag. Alternatively, the wave blocking block or the like may be installed at a predetermined installation location by removing the float and sinking the wave blocking block or the like in the sea.

  When the construction method by the operation of the air bag etc. of the wave-blocking block structure 100 shown in FIG. 22 is shown, the air bag 70, the air bag and the float are attached to the wave-breaking block etc. Therefore, the scale of necessary cranes, winches, etc. can be greatly reduced, and the construction cost can be reduced. Also, in general, both the crane ship and the breakwater block suspended in the water are constantly moving separately in response to waves, so in order to install the breakwater block etc. at a predetermined installation location Requires advanced operations such as cranes and winches. However, in a mode in which the air bag 70 is attached to a wavebreak block or the like and the operation of the crane or winch and the valve operation of the plurality of air chambers 71 are used in combination, the load on the crane or winch is significantly reduced. Operation of cranes, winches, etc. becomes easy. In addition, a large-scale crane ship is required for the installation of breakwater blocks near the sea surface and on the sea surface. However, since the wavebreak blocks can be seen directly from the crane ship, they cannot be seen directly. Compared to the case in the sea, it is possible to easily operate a crane, a winch or the like.

  In addition, in another embodiment, the construction method of the wave-blocking block structure 100 near the sea surface or on the sea surface is, in another embodiment, newly installed on one end portion of an existing wave-breaking block or the like installed at a predetermined installation location. Place one end of a wave block, etc. on top of the existing wave-breaking block 1 by placing sleepers, flat bars, mold steel, etc. (hereinafter referred to as “sleepers”). Leveling the end face to be horizontal, sandwiching a roller between the leveled horizontal surface and the bottom surface of the wave-proof block or the like to be installed, horizontally pull the wave-proof block etc. to a predetermined position, Alternatively, a sleeper block or the like may be removed using a crane, jack, winch or the like while adjusting the height of the newly installed wavebreak block or the like, and the wavebreak block or the like may be installed at a predetermined position.

  The wave-blocking block structure 100 includes a wave-dissipating block 10 incorporated in the wave-blocking block 1 and a wave-dissipating block upper plate 10e and a wave-dissipating block lower plate 10f that protrude upward and downward. Since the portion 10k and the upper plate concave portion 10m and the lower plate concave portion 10n that are depressed in the vertical direction are provided, the wave blocking block 1 or the wave-dissipating block 10 is firmly stacked by fitting them in the vertical direction. It becomes possible. In addition, the breakwater block structure 100 or the breakwater block structure 101 is used in the construction site of a mass concrete structure such as a breakwater or a breakwater depending on the shape and area of the worksite. By adding or removing the wave block 10, it is possible to freely design the shape and size of the wave-blocking block structure 100 or the wave-dissipating block structure 101 as needed, and after the completion of the construction The shape can be easily changed.

  Specifically, the wave-blocking block structure 100 or the wave-breaking block structure 101 increases or decreases the number of wave-blocking blocks 1 or wave-breaking blocks 10, or the wave-blocking edge block array 1 b or wave-breaking connection block 11. The decoupling edge linking block 12, the decoupling edge linking block array 12b, the decelerating corner linking block array 12c, or the like can be used or not used. At this time, the wave-blocking block structure 100 or the wave-dissipating block structure 101 is formed by vertically stacking the edges or providing steps on the edges, so that the height, the normal gradient of the edges, and the cross-section can be selected according to the site. A wave-blocking block structure 100 or a wave-dissipating block structure 101 having a longitudinal section can be constructed. As a result, the breakwater block structure 100 or the breakwater block structure 101 increases the amount of overtopping transmission waves from the breakwater or the breakwater due to a larger wave than expected, and hinders calmness in the harbor. In this case, the breakwater or breakwater can be easily raised even after the breakwater or breakwater is constructed.

  As mentioned above, although the example of embodiment of this invention was demonstrated in detail, all the embodiment mentioned above showed only the example of actualization in implementing this invention, and these are the technical aspects of this invention. The range should not be construed as limiting.

1: Wave block 1a: Wave block array 1b: Wave block block array 2: Land room 4: Wave chamber 6: Sea room 10: Wave block 10a: Semi wave block 10e: Wave block Upper plate 10f: Wave-dissipating block lower plate 10ae: Semi-wave-dissipating block upper plate 10af: Semi-wave-dissipating block lower plate 10am: Semi-upper plate concave portion 10an: Semi-lower plate concave portion 10g: Connecting column 10j: Upper plate convex portion 10k: Lower Plate convex portion 10m: Upper plate concave portion 10n: Lower plate concave portion 11: Wave-dissipating connection block 11a: Wave-dissipating connection block array 12: Wave-dissipating edge connecting block 12a: Wave-dissipating both-edge connecting block 12b: Wave-dissipating edge Connection block array 12c: Wave-dissipating corner connection block array 14: Weight block 14a: Weight connection block 14b: Weight edge connection block 14c: Weight corner connection block array 41 Breakwater plate 41a: Sakanadoriana 42: side wall panels 43: breakwater plate reinforcing side walls 43a: cantilever reinforced sidewall 43 b: side wall panels reinforced sidewalls 43c: cushioning sidewall A
43d: Impact relaxation side wall B
44: Breaking plate extending portion 70: Air bag 71: Air chamber 80: Carrier boat 81: Carrier boat opening 82: Tower 83: Cross beam 84: Hinge 85: Traveling beam 86: Hoist type crane 100: Wave blocking block structure Body 101: Wave-dissipating block structure

Claims (6)

A wave-dissipating connection block (11) that reduces the wave power of waves in the coastal area,
A land side room (2) provided on the land side, and a sea side room (6) provided on the sea side of the land side room (2),
The land side chamber (2) and the sea side chamber (6) are formed in a straight, substantially rectangular parallelepiped shape by combining the land side chamber (2) and the sea side chamber (6).
The land-side chamber (2) and the sea-side chamber (6) of the wave-dissipating connection block (11) have side surfaces of substantially the same shape and the same dimensions of the wave-dissipating blocks (10) of the substantially same shape and the same size. Connected in a straight line,
The height of each wave-dissipating block (10) is substantially the same as the height of the land-side room (2) and sea-side room (6) of the wave-dissipating connection block (11),
The width of each wave-dissipating block (10) is substantially the same as the width of the land-side room (2) and the sea-side room (6) of the wave-dissipating connection block (11),
Each wave-dissipating block (10) includes a wave-dissipating block upper plate (10e) and a wave-dissipating block lower plate (10f), and a plurality of wave-dissipating block upper plate (10e) and wave-dissipating block lower plate (10f). A connecting pillar (10 g),
Each wave-dissipating block upper plate (10e) constituting the upper plate of the land side chamber (2) and the sea side chamber (6) has a side surface formed in a substantially vertical plane and a planar shape formed in a substantially rectangular shape. The upper plate projection (10j) having a substantially quadrangular pyramid shape protruding upward at the four corners of the upper surface, and the upper plate recess (10m) having a substantially inverted quadrangular pyramid shape recessed downward at the approximate center of the upper surface And formed,
Each wave-dissipating block lower plate (10f) constituting the lower plate of the land side chamber (2) and the sea side chamber (6) has a side surface formed in a substantially vertical plane and a planar shape formed in a substantially rectangular shape. The lower plate convex portion (10k) having a substantially inverted quadrangular truncated pyramid shape protruding downward at the four corners of the lower surface, and the lower plate concave portion (10n) having a substantially quadrangular pyramid shape recessed upward at the substantially central portion of the lower surface And formed,
The wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f) have substantially the same thickness and are substantially symmetrical in the vertical direction. The wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f) The upper surface and the lower surface are substantially parallel to each other and the planar shape is substantially the same shape and the same size,
The upper surface of the wave-dissipating block upper plate (10e) and the lower surface of the wave-dissipating block lower plate (10f) are the upper surface of the upper plate convex portion (10j) and the lower surface of the upper plate concave portion (10m). And the lower surface of the lower plate convex portion (10k) and the upper surface of the lower plate concave portion (10n) of the wave-dissipating block lower plate (10f) are formed substantially parallel to each other and substantially horizontal,
The upper plate protrusions (10j) and the lower plate protrusions (10k) of the wave-dissipating block (10) have substantially the same shape and dimensions as each other, and the planar shape is substantially similar to the planar shape of the wave-dissipating block (10). Formed into
The upper plate recess (10m) and the lower plate recess (10n) of the wave-dissipating block (10) have substantially the same shape and dimensions as each other, and the planar shape is substantially similar to the planar shape of the wave-dissipating block (10),
The side surface of the wave-dissipating block upper plate (10e) and the side surface of the wave-dissipating block lower plate (10f) each have a common substantially vertical plane facing the same direction,
The short side and the long side of the planar shape of the upper surface of the wave-dissipating block upper plate (10e) and the lower surface of the wave-dissipating block lower plate (10f), and the upper plate protrusions (10j) on the upper surface of the wave-dissipating block upper plate (10e) ), The upper plate concave portion (10 m), the lower plate convex portion (10k) and the lower plate concave portion (10n) of the lower surface of the wave-dissipating block lower plate (10f). The sides and the long sides of each other form a substantially parallel line facing the same direction,
The two outer side surfaces of the upper plate convex portion (10j) of the wave-dissipating block (10) sandwich the corners of the wave-dissipating block upper plate (10e) having the upper plate convex portion (10j). The upper plate (10e) has two substantially vertical planes extending from two side surfaces, and the same substantially vertical plane respectively facing the same direction,
The two outer side surfaces of the lower plate projection (10k) of the wave-dissipating block (10) sandwich the corner of the wave-dissipating block lower plate (10f) having the lower plate projection (10k). There are two substantially vertical planes extending from the two side surfaces of the lower plate (10f) and the same substantially vertical plane respectively facing the same direction,
The plurality of connecting pillars (10g) of each wave-dissipating block (10) includes a wave-dissipating block upper plate (10e) and a wave-dissipating block lower plate (10f), and the four corners and substantially the center of each wave-dissipating block (10). Are combined to form each wave-dissipating block (10) into a substantially rectangular parallelepiped outline,
The upper plate concave portion (10m) and the lower plate convex portion (10k) of the wave-dissipating block (10) are substantially in contact with the four wave-dissipating blocks (10) having substantially the same shape and the same dimensions. In this way, the outer edges of the plane shape of the four wave-dissipating blocks (10) are assembled so as to be substantially similar to the plane shape of the wave-dissipating block (10), and each wave-dissipating block (10 ) The lower edge of the flat plate (10k), each of the four lower plate protrusions (10k), each of which has a flat shape, is substantially similar to the flat shape of the wave-dissipating block (10). None, this large lower plate convex portion is formed so that it can be fitted into the upper plate concave portion (10m) of the adjacent lower wave-dissipating block (10),
The lower plate concave portion (10n) and the upper plate convex portion (10j) of the wave-dissipating block (10) are substantially in contact with the four wave-dissipating blocks (10) having substantially the same shape and the same side surfaces. In this way, the outer edges of the plane shape of the four wave-dissipating blocks (10) are assembled so as to be substantially similar to the plane shape of the wave-dissipating block (10), and each wave-dissipating block (10 ) The upper edge of the flat plate formed by assembling four upper plate protrusions (10j) each consisting of one upper plate protrusion (10j) is substantially similar to the flat shape of the wave-dissipating block (10). None, the wave-dissipating connection block is formed so that the large upper-plate convex part can be fitted into the lower-plate concave part (10n) of the adjacent upper-layer wave-dissipating block (10). A wave-breaking block (1) that reduces, quenches and breaks the wave power in the coast,
The land side room (2) provided on the land side, the wave preventing room (4) provided on the sea side of the land side room (2), and the sea side room (6 provided on the sea side of the wave preventing room (4)) )
The land side chamber (2), the wave preventing chamber (4), and the sea side chamber (6) are connected to the land side chamber (2), the wave preventing chamber (4), and the sea side chamber (6) to form a straight, substantially rectangular parallelepiped shape. Formed into
The land-side chamber (2) and the sea-side chamber (6) constituting the wave-breaking block (1) share the side surfaces of the substantially the same shape and the same size of several wave-dissipating blocks (10) having a substantially rectangular parallelepiped shape. The substantially rectangular parallelepiped wave-dissipating connection block (11) connected in a straight line and the wave-dissipating block (10) at the end of the wave-dissipating connection block (11) in the longitudinal direction of the wave-blocking block (1) Cut in half at the approximate center of the end wave-dissipating block (10) in a substantially vertical plane substantially perpendicular to the axis, and on the side connected to the other wave-dissipating connection block (11) from which the cut pieces have been removed A semi-quenching block (10a),
The height of the wave-dissipating block (10) is substantially the same height as the land-side room (2) and the sea-side room (6) of the wave-breaking block (1),
The width of the wave-dissipating block (10) is substantially the same width as the width of the land-side room (2) and the sea-side room (6) of the wave-breaking block (1).
The land-side room (2) and the sea-side room (6) that constitute the wave-breaking block (1) have the wave-dissipating block (10) at one end of the wave-dissipating connection block (11) as the length of the wave-breaking block (1). The remainder of the wave-dissipating connection block (11) from which the cut piece has been removed by cutting in half at the approximate center of the wave-dissipating block (10) at the end on a substantially vertical plane substantially perpendicular to the axial center axis. It is made up of a part, a decoupling edge connection block (12),
Each wave-dissipating block (10) couples the wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f), and the wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f). Connecting pillar (10 g)
Each wave-dissipating block upper plate (10e) constituting the upper plate of the land side chamber (2) and the sea side chamber (6) has a side surface formed in a substantially vertical plane and a planar shape formed in a substantially rectangular shape. The upper plate convex portion (10j) having a substantially quadrangular pyramid shape protruding upward at the four corners of the upper surface, and the upper plate concave portion having a substantially inverted quadrangular pyramid shape recessed downward at the substantially central portion of the upper surface ( 10m) is formed,
Each wave-dissipating block lower plate (10f) constituting the lower plate of the land side chamber (2) and the sea side chamber (6) has a side surface formed in a substantially vertical plane and a planar shape formed in a substantially rectangular shape. The lower plate convex portion (10k) having a substantially inverted quadrangular pyramid shape projecting downward at the four corners of the lower surface, and the lower plate concave portion having a substantially quadrangular pyramid shape depressed upward at the substantially central portion of the lower surface ( 10n) is formed,
The wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f) have substantially the same thickness and are substantially symmetrical in the vertical direction. The wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f) The upper surface and the lower surface are substantially parallel to each other and the planar shape is substantially the same shape and the same size,
The upper surface of the wave-dissipating block upper plate (10e) and the lower surface of the wave-dissipating block lower plate (10f) are the upper surface of the upper plate convex portion (10j) and the lower surface of the upper plate concave portion (10m). And the lower surface of the lower plate convex portion (10k) and the upper surface of the lower plate concave portion (10n) of the wave-dissipating block lower plate (10f) are formed substantially parallel to each other and substantially horizontal,
The upper plate protrusions (10j) and the lower plate protrusions (10k) of the wave-dissipating block (10) have substantially the same shape and dimensions as each other, and the planar shape is substantially similar to the planar shape of the wave-dissipating block (10). Formed into
The upper plate recess (10m) and the lower plate recess (10n) of the wave-dissipating block (10) have substantially the same shape and dimensions as each other, and the planar shape is substantially similar to the planar shape of the wave-dissipating block (10),
The side surface of the wave-dissipating block upper plate (10e) and the side surface of the wave-dissipating block lower plate (10f) each have a common substantially vertical plane facing the same direction,
The short side and the long side of the planar shape of the upper surface of the wave-dissipating block upper plate (10e) and the lower surface of the wave-dissipating block lower plate (10f), and the upper plate protrusions (10j) on the upper surface of the wave-dissipating block upper plate (10e) ), The upper plate recess (10m) and the lower plate protrusion (10k) on the lower surface of the wave-dissipating block lower plate (10f) and the short side and the long side of each planar shape of the lower plate recess (10n) The short sides and the long sides of each other form a substantially parallel line facing the same direction,
The two outer side surfaces of the upper plate convex portion (10j) of the wave-dissipating block (10) sandwich the corners of the wave-dissipating block upper plate (10e) having the upper plate convex portion (10j). The upper plate (10e) has two substantially vertical planes extending from two side surfaces, and the same substantially vertical plane respectively facing the same direction,
The two outer side surfaces of the lower plate projection (10k) of the wave-dissipating block (10) sandwich the corner of the wave-dissipating block lower plate (10f) having the lower plate projection (10k). There are two substantially vertical planes extending from the two side surfaces of the lower plate (10f) and the same substantially vertical plane respectively facing the same direction,
The plurality of connecting pillars (10g) of each wave-dissipating block (10) includes a wave-dissipating block upper plate (10e) and a wave-dissipating block lower plate (10f) at the four corners and substantially the center of each wave-dissipating block (10). Are combined to form each wave-dissipating block (10) into a substantially rectangular parallelepiped outline,
The upper plate concave portion (10m) and the lower plate convex portion (10k) of the wave-dissipating block (10) are substantially in contact with the four wave-dissipating blocks (10) having substantially the same shape and the same dimensions. In this way, the outer edges of the plane shape of the four wave-dissipating blocks (10) are assembled so as to be substantially similar to the plane shape of the wave-dissipating block (10), and each wave-dissipating block (10 ) The lower edge of the flat plate (10k), each of the four lower plate protrusions (10k), each of which has a flat shape, is substantially similar to the flat shape of the wave-dissipating block (10). None, this large lower plate convex portion is formed so that it can be fitted into the upper plate concave portion (10m) of the adjacent lower wave-dissipating block (10),
The lower plate concave portion (10n) and the upper plate convex portion (10j) of the wave-dissipating block (10) are substantially in contact with the four wave-dissipating blocks (10) having substantially the same shape and the same side surfaces. In this way, the outer edges of the plane shape of the four wave-dissipating blocks (10) are assembled so as to be substantially similar to the plane shape of the wave-dissipating block (10), and each wave-dissipating block (10 ) The upper edge of the flat plate formed by assembling four upper plate protrusions (10j) each consisting of one upper plate protrusion (10j) is substantially similar to the flat shape of the wave-dissipating block (10). None, this large upper plate convex portion is formed so that it can be fitted into the lower plate concave portion (10n) of the adjacent upper wave-dissipating block (10),
The wave preventing chamber (4) has a wave preventing plate (41) and a side wall plate (42),
The wave-breaking plate (41) provided inside the harbor of the wave-breaking room (4) is on the wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f) or the semi-wave-dissipating block of the land-side room (2). It is coupled to the plate (10ae) and the lower half wave-dissipating block lower plate (10af), and is formed in a substantially vertical flat plate shape in a direction substantially perpendicular to the longitudinal central axis of the wave-blocking block (1),
The side wall plates (42) provided on both sides of the breakwater chamber (4) are the wave-dissipating block upper plate (10e) and the wave-dissipating block lower plate (10f) or the half-wave-dissipating block upper plate ( 10ae) and the lower half-wave block lower plate (10af), the wave-proof plate (41) and the wave-dissipating block upper plate (10e) of the land side chamber (2), and the wave-dissipating block lower plate (10f) or the half-wave-dissipating block The outer surface of the side wall plate (42) is substantially the same as the outer surface of the wave blocking block (1) in the longitudinal direction of the wave blocking block (1). Forming the same substantially vertical plane, the inner side surface of the side wall plate (42) is substantially parallel to the outer side surface of the side wall plate (42), and the left and right side wall plates (42) are formed to have substantially the same thickness,
The wave-breaking chamber (4) has a substantially vertical flat plate-shaped wave-breaking plate (41), and substantially vertical flat-plate-shaped side wall plates (42) are arranged in a zigzag manner on the top and bottom, so that the wave-breaking chamber (4) A wave-blocking block characterized by having a space penetrating in the vertical direction. A fish passage hole (41a) for communicating the land-side chamber (2) and the wave-breaking chamber (4) is formed in the wave-breaking plate (41) according to claim 2. Wavebreak block. A plurality of wave-breaking blocks (1) according to claim 2 or 3 are arranged so that a central axis in a major axis direction of each wave-breaking block (1) is approximately in a direction from the sea floor side to the sea side and from the sea side to the port inside. The contact surfaces of the substantially vertical and substantially identical side surfaces that are substantially parallel and substantially parallel to the central axis in the major axis direction of the two rows of wave blocking blocks (1) of the lower first block layer are arranged adjacent to each other in parallel. The upper layer is constructed by stacking up and down in a staggered manner so that the central axis in the major axis direction of the row of wave blocking blocks (1) in the upper second block layer adjacent to the first block layer substantially overlaps. A wave-blocking block structure (100) comprising:
A plurality of wave blocking blocks (1) having substantially the same type and the same size, arranged side by side in contact with each other on the lower first block layer in common, and parallel to the first block layer A plurality of substantially the same type and the same size wave-blocking blocks installed side by side in contact with each other on the second block layer of the upper layer adjacent to the first block layer in the same direction with the same side surfaces having the same type and the same size in common. 1)
The wave prevention plate (41) of the wave prevention chamber (4) is provided inside the wave prevention block structure (100) in which the wave prevention blocks (1) are stacked in a zigzag manner in the vertical direction. Are set so that they form substantially the same vertical flat plate, and the direction of each wave blocking plate (41) is substantially perpendicular to the direction from the open sea side toward the inside of the port. Wavebreak blocks (1) are stacked,
Side surfaces of substantially the same shape and the same dimensions of the substantially rectangular parallelepiped wave-dissipating block (10) constituting the land-side chamber (2) and the sea-side chamber (6) of the wave-blocking block (1) of the first block layer. The outer edges of the four planar shapes of the wave-dissipating block (10) are assembled so that they are almost in contact with each other so that they are substantially similar to the planar shape of the wave-dissipating block (10). Four upper plate projections (10j) each consisting of each one of the upper plate projections (10j) protruding upward from each wave-dissipating block upper plate (10e) of the block layer are assembled to form a first A large upper plate convex portion of the first block layer is formed, and the outer edge of the planar shape is substantially similar to the planar shape of the wave-dissipating block (10). Installed adjacent to the upper layer at the center of the outer edge of the four wave-dissipating blocks (10) of one block layer The, fitted to the lower plate recess of wave dissipating blocks lower plate of one wave dissipating blocks of the second blocking layer (10) (10f) (10n),
In the same manner as described above, the outer edges of the four planar shapes of the wave-dissipating block (10) of the first block layer are assembled so as to be substantially similar to the planar shape of the wave-dissipating block (10). Downward from the four corners of the wave-dissipating block lower plate (10f) of one wave-dissipating block (10) of the second block layer, which is installed adjacent to the upper layer at the center of the planar outer edge of the block layer The projecting four lower plate projections (10k) are respectively inserted into a quarter of the upper plate recesses (10m) of the four wave-dissipating block upper plates (10e) of the first block layer,
Each top plate convex portion (10j) and each bottom plate convex portion (10k) and each top of each wave-dissipating block (10) constituting the land side chamber (2) and the sea side chamber (6) of the breakwater block (1) The wave-breaking blocks (1) can be stacked in layers by fitting the plate depressions (10m) and the lower plate depressions (10n) to each other in a zigzag manner in the vertical direction. Block structure. A wave-blocking plate extending portion (44) is formed by extending the wave-blocking plate (41) upward of the wave-blocking block (1) installed in the uppermost layer according to claim 4 to extend the wave-breaking plate. The wave-blocking block structure according to claim 4, wherein an upper portion of the portion (44) is inclined toward the sea side. A construction method of a wave-blocking block structure (100) for building the wave-blocking block structure (100) according to claim 4 or 5,
A number of cross beams (83) that can be set and removed are passed to a base boat opening (81) of a base boat (80) provided with a base boat opening (81) in a substantially central portion, and a cross beam (83 The wave-blocking block (1) is placed on the upper part of the wave-breaking block (1), and the wave-breaking block (1) is tightly coupled to the trolley (80) so that the wave-breaking block (1) does not move due to the shaking of the wave. 1) a transport process for transporting to a predetermined installation location;
An installation step of suspending the wave-blocking block (1) from the opening (81) at the center of the carriage (80) and installing the wave-blocking block (1) at a predetermined installation location. A construction method of a wave-breaking block structure as a feature.

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