JP2019184547A - Shield wall - Google Patents

Abstract

To provide a shield wall capable of improving earthquake proofness while maintaining shield property.SOLUTION: A shield wall 1 is a shield wall comprising a plurality of shield blocks vertically stacked, the shield blocks 10-70 comprise a first shield block and a second shield block, and a middle step shield block 30 being the first shield block comprises a middle step side shield block body 31 and a middle step side salient provided on a top face of the middle step side shield block body 31. A middle step shield block 40 being the second shield block comprises a middle step side shield block body and a middle step recess provided on a lower face of the middle step side shield block body. The top face of the middle step side shield block body 31 of the middle step shield block 30 is formed as a first shield plane 31a which is non-parallel to a radial direction of a radiant ray, the lower face of the middle step side shield block body of the middle step shield block 40 is formed as a second shield plane 31d formed corresponding to the first shield plane 31a.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a shielding wall.

  2. Description of the Related Art Conventionally, techniques for shielding emitted radiation have been proposed for facilities that handle radioactive materials (for example, nuclear facilities) or facilities that generate radiation (for example, accelerator facilities). In this technique, for example, a shielding wall is configured by stacking a plurality of shielding blocks formed of a radioactive shielding material composition in the vertical direction. The mating surface of the adjacent shielding blocks (specifically, the upper surface or the lower surface of the shielding block) among the plurality of shielding blocks is a non-linear surface that is non-linear from the surface of the shielding wall to the back surface, and It forms in the non-linear surface formed over the full length of the width direction of the said mating surface. With such a configuration, it is possible to prevent radiation from passing through a gap between adjacent shielding blocks, and it is possible to effectively shield the radiation (for example, see Patent Document 1).

JP 57-24752 A

  However, in the above-described conventional technology, as described above, the mating surface of the adjacent shielding blocks is a non-linear surface that is non-linear from the surface to the back surface of the shielding wall, and the width direction of the mating surface Since this is a non-linear surface formed over the entire length, the movement of the shielding block in the width direction is allowed. For example, when a seismic force acts on the shielding wall, a part of the shielding block falls off. There was a fear. Therefore, there is room for improvement from the viewpoint of improving earthquake resistance while maintaining shielding properties.

  This invention is made | formed in view of the above, Comprising: It aims at providing the shielding wall which can improve earthquake resistance, maintaining shielding property.

  In order to solve the above-described problems and achieve the object, the shielding wall according to claim 1 is a shielding wall for shielding radiation, and includes a plurality of shielding blocks stacked in the vertical direction. The plurality of shielding blocks include a first shielding block and a second shielding block that is adjacent to the first shielding block and located above the first shielding block, and the first shielding block. The block includes a first shielding block main body, and at least one or more protrusions provided on an upper surface of the first shielding block main body and projecting upward, and the second shielding block includes a second shielding block. At least one block body and at least one concave portion provided on the lower surface of the second shielding block main body and recessed upward, the horizontal movement of the convex portion being restricted by the concave portion, A convex portion and a concave portion that can be fitted, and at least part of the upper surface of the first shielding block main body is a shielding surface that is non-parallel to the radiation direction of the radiation and extends over the entire length in the width direction of the upper surface. It is formed as a first shielding surface that is a shielding surface to be formed, and at least a part of the other lower surface of the second shielding block body is a shielding surface formed so as to correspond to the first shielding surface. The second shielding surface is a shielding surface that can come into contact with the first shielding surface.

  The shielding wall according to claim 2 is the shielding wall according to claim 1, wherein each of the first shielding surface and the second shielding surface is inclined downward toward the outside of the shielding wall. did.

  The shielding wall according to claim 3 is the shielding wall according to claim 1 or 2, wherein at least one of an upper surface portion of the convex portion or an opposing portion facing the upper surface portion of the convex portion in the concave portion, It was formed as a third shielding surface that is a shielding surface that is not parallel to the radiation direction of the radiation and is formed over the entire length in the width direction of the portion.

  The shielding wall according to claim 4 is the shielding wall according to any one of claims 1 to 3, wherein the shielding wall is installed in the vicinity of the opening, and seals the opening. The shielding wall is installed such that the lower surface of the shielding block located at the lowermost position among the plurality of shielding blocks is located below the lower end of the opening.

  According to the shielding wall of Claim 1, the 1st shielding block is provided with the 1st shielding block main body, and the convex part provided in the upper surface of the 1st shielding block main body at least 1 or more, The 2nd shielding The block is a second shielding block main body and at least one concave portion provided on the lower surface of the second shielding block main body, and is fitted to the convex portion so that the horizontal movement of the convex portion is restricted by the concave portion. Since the concave portion is provided, the horizontal movement of the first shielding block can be restricted by fitting the convex portion and the concave portion, and the first shielding block can be prevented from falling off. Further, at least a part of the upper surface of the first shielding block main body is formed as a first shielding surface which is a first shielding surface which is not parallel to the radiation direction of the radiation and is formed over the entire length in the width direction of the upper surface, 2 Since at least a part of the other lower surface of the shielding block body is formed as a second shielding surface formed so as to correspond to the first shielding surface, radiation is shielded by the first shielding surface or the second shielding surface. The radiation can be prevented from passing through the shielding wall. Therefore, it is possible to improve the earthquake resistance while maintaining the shielding property as compared with the conventional technique (a technique in which the mating surface of the adjacent shielding blocks is a non-linear surface formed over the entire length in the width direction).

  According to the shielding wall of the second aspect, each of the first shielding surface and the second shielding surface is formed so as to be inclined downward toward the outside of the shielding wall. Compared with the case where it is formed so as to incline upward as it goes to the outside, it is possible to suppress the accumulation of water on the upper surface of the first shielding block main body, and it is possible to suppress the deterioration of the shielding wall due to water immersion.

  According to the shielding wall of Claim 3, at least any one of the upper surface part of a convex part or the opposing part which opposes the upper surface part of the convex part in a recessed part is a 3rd shielding surface non-parallel to the radiation direction of a radiation. Since the third shielding surface is formed over the entire length in the width direction of the portion, radiation can be shielded by the upper surface portion of the convex portion or the upper surface portion of the concave portion, and the upper surface portion of the convex portion or the upper surface of the concave portion. The shielding property can be improved as compared with the case where the portion is flat.

  According to the shielding wall of the fourth aspect, since the shielding wall is installed so that the lower surface of the lowermost shielding block is located below the lower end of the opening, the lower surface of the lowermost shielding block is Compared with the case where it is flush with the lower end of the opening, it is possible to avoid the passage of radiation through the gap between the lower surface of the lowermost shielding block and the installation surface, and the shielding performance can be further improved.

It is a front view which shows the outline | summary of the shielding wall which concerns on embodiment of this invention. FIG. 2 is a right side view of FIG. 1 (partially omitted). It is AA arrow sectional drawing of FIG. It is a figure which shows a middle stage shielding block, (a) is a perspective view, (b) is a BB arrow sectional drawing. It is a figure which shows a lower shield block, (a) is a perspective view, (b) is CC sectional view taken on the line. It is a figure which shows an upper stage shielding block, (a) is a perspective view, (b) is DD sectional view taken on the line. It is a figure which shows the modification of a middle stage shielding block, (a) is a perspective view, (b) is EE arrow sectional drawing. It is a figure which shows the modification of a middle stage shielding block, (a) is a perspective view, (b) is FF arrow sectional drawing. It is a figure which shows the modification of a middle stage shielding block, (a) is a perspective view, (b) is GG arrow sectional drawing. It is sectional drawing which shows the modification of a middle stage shielding block, Comprising: It is sectional drawing corresponding to FIG.4 (b). It is a side view which shows the modification of a shielding wall, Comprising: It is a side view corresponding to FIG. It is a side view which shows the modification of a shielding wall, Comprising: It is a side view corresponding to FIG. It is sectional drawing which shows the modification of a shielding wall, Comprising: It is sectional drawing corresponding to FIG.

  Embodiments of a shielding wall according to the present invention will be described below in detail with reference to the accompanying drawings. First, [I] the basic concept of the embodiment will be described, then [II] the specific content of the embodiment will be described, and finally, [III] a modification to the embodiment will be described. However, the present invention is not limited to the embodiments.

[I] Basic Concept of Embodiment First, the basic concept of the embodiment will be described. The embodiment is generally a shielding wall for shielding radiation, and relates to a shielding wall including a plurality of shielding blocks stacked in the vertical direction. The application target of the shielding wall is arbitrary, but for example, a building where radiation may be emitted from the inside of the building to the outside (for example, a nuclear facility, an accelerator facility, a research facility where radiation is used, It can be applied to medical facilities) and buildings where radiation may be emitted from the outside to the inside of the building. Although the specific kind of radiation is arbitrary, it is a concept including, for example, alpha rays (α rays), beta rays (β rays), gamma rays (γ rays), X rays, and neutron rays. In addition, in the embodiment, the radiation direction of radiation is described as a direction substantially along the horizontal direction (the front-rear direction described later or the left-right direction described later). However, the present invention is not limited to this. The direction may be the same.

[II] Specific Contents of Embodiment Next, specific contents of the embodiment will be described.

(Constitution)
First, the configuration of the shielding wall according to the embodiment and the configuration of the building where the shielding wall is installed will be described. FIG. 1 is a front view showing an outline of a shielding wall according to an embodiment of the present invention. FIG. 2 is a right side view of FIG. FIG. 3 is a cross-sectional view taken along the line AA in FIG. 1 (partially omitted). Here, the X direction in FIG. 1 is the left-right direction or the width direction of the shielding wall (the −X direction is the left direction of the shielding wall, the + X direction is the right direction of the shielding wall), and the Y direction in FIG. + Y direction is the front direction of the shielding wall, −Y direction is the rear direction of the shielding wall, Z direction in FIG. 1 is the vertical direction of the shielding wall (+ Z direction is the upward direction of the shielding wall, −Z direction is the downward direction of the shielding wall) ).

(Configuration-Building)
The building 1 will be described as a research facility where radiation is used. This building 1 is made of, for example, reinforced concrete, and is provided in a predetermined site. As shown in FIGS. 1 to 3, a floor portion 1a, a pillar portion (not shown), a beam portion (not shown) ) And the wall 1b.

  The floor portion 1a is a floor constituting the building 1, and a plurality of floor portions 1a are arranged in parallel in the vertical direction with a space between each other. Moreover, a pillar part is a pillar which supports the floor part 1a, and two or more are provided between floor parts 1a. The beam portions are beams that support the floor portion 1a, and a plurality of beam portions are provided so as to come into contact with the lower surface of each floor portion 1a. The wall portion 1b is a wall for partitioning the floor portions 1a, and a plurality of the wall portions 1b are provided between the floor portions 1a.

  As shown in FIGS. 1 to 3, an opening 1c and a door 1d are provided in the front wall 1b among the plurality of walls 1b. Among these, the opening part 1c is an opening for carrying in and out various apparatuses to the research facility. As shown in FIG. 1, the opening 1 c is formed in a horizontally long rectangular shape, and is arranged so that the lower end of the opening 1 c is positioned on the upper surface of the floor surface. Further, the specific size of the opening 1c is arbitrary. For example, the length and the vertical length of the opening 1c can be loaded into and unloaded from the various devices. The length is set. The door 1d is for opening and closing the opening 1c. For example, the door 1d is configured by using a known door (for example, a double-open door), and is a hinge member (not shown) with respect to the wall 1b of the building 1. (For example, a known hinge) is rotatably supported.

(Configuration-shielding wall)
Returning to FIG. 1, the shielding wall 2 is a wall for shielding radiation (not shown) emitted toward the outside of the building 1 through the opening 1 c (from right to left in FIG. 2). And it is a wall for sealing the opening part 1c. As shown in FIGS. 1 to 3, the shielding wall 2 is provided outside the building 1. Specifically, the shielding wall 2 is located in the vicinity of the opening 1 c and does not contact the wall 1 b of the building 1. In position, it is erected with respect to the installation surface 3. In the embodiment, the installation surface 3 is provided below the floor 1a of the building 1 as shown in FIG. Further, in FIGS. 1 to 3, the shielding wall 2 is provided at a position where the opening and closing of the door 1d is prevented. The reason is as follows. That is, it is for giving priority to shielding radiation rather than opening and closing the opening 1c by the door 1d, and since the frequency of opening and closing the door 1d is low, it is difficult for the use of the door 1d to be hindered. It is.

  Further, the specific shape and size of the shielding wall 2 are arbitrary, but in the embodiment, the shape and size are set such that the entire opening 1c is covered by the shielding wall 2 when viewed from the front side. ing. Specifically, the front shape of the shielding wall 2 is set to a horizontally long rectangular shape as shown in FIG. Moreover, about the length (width) of the left-right direction of the shielding wall 2, it is set longer than the length of the left-right direction of the opening part 1c. The length (depth) of the shielding wall 2 in the front-rear direction is desirably set as short as the shielding performance of the shielding wall 2 reaches a desired shielding performance, and is set based on experimental results and the like. . The vertical length (height) of the shielding wall 2 is set to be longer than the vertical length of the opening 1c.

  Moreover, this shielding wall 2 is comprised including the shielding blocks 10-70, as shown in FIG. 1, FIG.

(Configuration-shielding wall-shielding block)
Returning to FIG. 1, the shielding blocks 10 to 70 are basic structures of the shielding wall 2, and as shown in FIGS. 1 and 2, the shielding blocks 10 to 70 are vertically stacked on the installation surface 3. Are provided in the order of shielding blocks 10 to 70 from below to above.

  The material of the shielding blocks 10 to 70 is arbitrary, but a material having high radiation shielding properties is desirable. In the embodiment, the shielding blocks 10 to 70 are made of ordinary concrete. However, it is not limited to this, and it may be made of a material other than ordinary concrete. For example, you may comprise with material (polyethylene, paraffin, gypsum) with high hydrogen density. Alternatively, it may be composed of a material containing an element selected from the group consisting of boron, boron mineral (such as colemanite), gadolinium, cadmium, and lithium or an element having a large thermal neutron absorption cross section of its isotope. Good. Alternatively, it is composed of a material containing at least one particle selected from the group consisting of lead, tungsten, bismuth, iron, iron oxide, iron ore, magnetite, hematite, barite, barium, and barium compounds. Also good.

  In the following description, the shielding block 10 located at the lowermost position among the shielding blocks 10 to 70 will be referred to as a “lower shielding block 10”, and the shielding block 70 located at the uppermost position will be referred to as an “upper shielding block” as necessary. 70 ”, and the shielding blocks 20 to 60 located between the upper shielding block 70 and the lower shielding block 10 are referred to as“ middle shielding blocks 20 to 60 ”. Further, when it is not necessary to distinguish these shielding blocks 10 to 70, they are simply referred to as “shielding block 80”.

(Configuration-shielding wall-details of the configuration of the shielding wall)
Next, details of the configuration of the shielding wall 2 will be described. In the following, regarding the details of the configuration of the shielding wall 2, the details of the configuration of the shielding block 80 and the details of the configuration other than the shielding block 80 will be described.

(Configuration-shielding wall-details of shielding wall configuration-details of shielding block configuration-middle shielding block)
First, among the details of the configuration of the shielding block 80, the details of the configuration of the middle shielding blocks 20 to 60 will be described. 4A and 4B are diagrams showing the middle shielding block 30, in which FIG. 4A is a perspective view, and FIG. 4B is a cross-sectional view taken along line BB. However, since the configuration of each of the middle shielding blocks 20 to 60 is substantially the same, only the configuration of the middle shielding block 30 will be described below. The middle shielding block 30 can be manufactured in any shape, method, and material unless otherwise specified.

  In the embodiment, as shown in FIG. 1, the middle shielding block 30 is a first shielding block located below the middle shielding block 40 and a second shielding block located above the middle shielding block 20. It is. As shown in FIGS. 1, 2, and 4, the middle shielding block 30 includes a middle shielding block main body 31, a middle projection 32 provided on the upper surface of the middle shielding block main body 31, and a middle shielding. And a middle recess 33 provided on the lower surface of the block body 31.

(Configuration-Shielding wall-Details of the configuration of the shielding wall-Details of the configuration of the shielding block-Middle stage shielding block-Middle stage shielding block body)
The middle-stage shielding block main body 31 is a basic structure of the middle-stage shielding block 30. The middle-stage shielding block main body 31 is formed in a long, substantially solid rectangular parallelepiped, and, as shown in FIGS. 2 and 4, the middle-stage shielding block main body 31 is between the middle-stage shielding block 20 and the middle-stage shielding block 40. The side shielding block main body 31 is provided so that the longitudinal direction thereof is substantially along the horizontal direction.

  Further, the specific size of the middle-stage shielding block main body 31 is arbitrary, but in the embodiment, it is set as follows. That is, the length (width) in the left-right direction of the middle shielding block main body 31 is set to be the same as the length in the left-right direction of the shielding wall 2 as shown in FIG. Further, the length in the front-rear direction (depth) of the middle shielding block main body 31 is set to be the same as the length in the front-rear direction of the shielding wall 2 as shown in FIG. The vertical length (height) of the middle shielding block main body 31 is set to be shorter than the vertical length of the shielding wall 2.

  The specific configuration of the middle-stage shielding block main body 31 is arbitrary, but in the embodiment, it is configured as follows.

  That is, first, at least a part of the upper surface of the middle-stage shielding block body 31 is a shielding surface that is not parallel to the radiation direction (the direction along the horizontal direction) and is the entire length in the width direction (left-right direction) of the upper surface. It is formed as a first shielding surface 31a which is a shielding surface formed over the entire area. Specifically, the first shielding surface 31a includes a front first shielding surface 31b and a rear first shielding surface 31c. Among these, the front first shielding surface 31 b is a shielding surface provided in a region from the front end portion of the upper surface to the middle-side convex portion 32 in the region of the upper surface of the middle-stage shielding block main body 31. It is formed so as to incline downward as it goes to the outside (front in FIG. 4) (in FIG. 4, it is formed with a straight slope). The rear first shielding surface 31c is a shielding surface provided in a region from the rear end portion of the upper surface to the middle convex portion 32 in the region of the upper surface of the middle-stage shielding block main body 31, and is a shielding wall. 2 is formed so as to incline downward toward the outer side (backward in FIG. 4) (in FIG. 4, it is formed by a linear slope). With such a configuration, radiation can be shielded by the first shielding surface 31a, and the passage of radiation through the gap between the middle shielding block 30 and the middle shielding block 40 can be avoided. Moreover, compared with the case where it forms so that it may incline upward as the 1st shielding surface 31a goes to the outer side of the shielding wall 2, it can suppress that water accumulates on the upper surface of the middle shielding block main body 31 of the middle shielding block 30. Therefore, deterioration of the shielding wall 2 due to water immersion can be suppressed.

  Further, at least a part of the lower surface of the middle shield block main body 31 is a shield surface formed so as to correspond to the first shield surface 31a of the middle shield block 20, and can contact the first shield surface 31a. It is formed as a second shielding surface 31d which is a shielding surface. Specifically, the second shielding surface 31d includes a front second shielding surface 31e and a rear second shielding surface 31f. Among these, the front-side second shielding surface 31e is a shielding surface provided in a region from the front end portion of the lower surface to the middle-side concave portion 33 in the region of the lower surface of the middle-stage shielding block main body 31, and It forms so that it may incline below as it goes to the outer side (front in FIG. 4) (it forms with the linear slope in FIG. 4). Further, the rear second shielding surface 31f is a shielding surface provided in a region from the rear end portion of the lower surface to the middle convex portion 32 in the region of the lower surface of the middle-stage shielding block main body 31, and is a shielding wall. 2 is formed so as to incline downward toward the outer side (backward in FIG. 4) (in FIG. 4, it is formed by a linear slope). With such a configuration, radiation can be shielded by the second shielding surface 31d, and radiation can be prevented from passing through the gap between the middle shielding block 20 and the middle shielding block 30. The “middle stage shielding block body 31” described above corresponds to the “first shielding block body” and the “second shielding block body” in the claims.

(Configuration-shielding wall-details of the configuration of the shielding wall-details of the configuration of the shielding block-middle stage shielding block-middle stage side convex part, middle stage side concave part)
The middle-stage convex portion 32 is a convex portion that fits into the middle-stage concave portion 33 (the same as the configuration of the middle-stage concave portion 33 of the middle-stage shielding block 30), and as shown in FIG. The block main body 31 is formed so as to protrude upward from the upper surface (specifically, the central portion in the front-rear direction of the upper surface). Further, the middle-stage concave portion 33 is a concave portion fitted to the middle-stage convex portion 32 of the middle-stage shielding block 20 (the same as the configuration of the middle-stage convex portion 32 of the middle-stage shielding block 30). It is formed so as to be recessed upward from the lower surface (specifically, the central portion of the lower surface in the front-rear direction).

  Here, the specific shapes and sizes of the middle-stage convex portion 32 and the middle-stage concave portion 33 are arbitrary, but in the embodiment, they are set as follows. That is, as shown in FIG. 4, the shape of the middle-stage convex portion 32 is set to a long rectangular parallelepiped, and the shape of the middle-stage concave portion 33 is set to a concave shape corresponding to the middle-stage convex portion 32. is doing. Further, it is desirable to set the sizes of the middle-stage convex portion 32 and the middle-stage concave portion 33 in consideration of the shear strength of the middle-stage convex portion 32, and are set based on experimental results and the like. Specifically, the length (width) in the left-right direction of the middle-stage convex portion 32 is set to be shorter than the length in the left-right direction of the middle-stage shielding block main body 31 in order to facilitate the construction of the shielding wall 2. In addition, the length (width) in the left-right direction of the middle-stage concave portion 33 is set slightly longer than the length in the left-right direction of the middle-stage convex portion 32. Further, the length in the front-rear direction (depth) of the middle-stage convex portion 32 is set to be shorter than the length in the front-rear direction of the middle-stage shielding block body 31 and the length in the front-rear direction of the middle-stage concave portion 33 ( The depth is set slightly longer than the length in the front-rear direction of the middle-stage convex portion 32. In addition, the vertical length (height) of the middle-stage convex portion 32 is shorter than the vertical length of the middle-stage shielding block main body 31 in order to maintain adhesion with the adjacent middle-stage shielding block 30. While being set, the length (depth) of the middle-stage concave portion 33 in the vertical direction is set slightly longer than the length of the middle-stage convex portion 32 in the vertical direction. With such a setting, the middle stage convex part 32 of the middle stage shielding block 30 and the middle stage side concave part 33 of the middle stage shielding block 40 are fitted, and the middle stage side convex part 32 of the middle stage shielding block 20 and the middle stage side of the middle stage shielding block 30. By fitting with the recess 33, it is possible to limit the horizontal movement of the middle shielding block 30 (specifically, movement in the left-right direction and the front-rear direction).

(Configuration-shielding wall-details of shielding wall configuration-details of shielding block configuration-middle shielding block-other configurations)
Further, although the specific configuration of the middle shielding block 30 is arbitrary, in the embodiment, as shown in FIG. 4, a reinforcing member 34 (for example, a part of a plurality of corners in the middle shielding block 30 is provided. , A known angle material) is provided over the entire length of the corner portion in the front-rear direction. Further, a chamfered portion 35 is formed on the other part of the plurality of corners in the middle shielding block 30 over the entire length of the corners in the front-rear direction. With such a configuration, it is possible to prevent the middle stage shielding block 30 from being damaged due to the middle stage shielding block 30 coming into contact with the middle stage shielding block 20 or the middle stage shielding block 40.

  The intermediate shielding block 30 may be formed by any method. For example, by placing ordinary concrete in a predetermined form and curing it for a predetermined period, the components of the intermediate shielding block 30 are integrally formed. (The same applies to the method of forming the upper shielding block 70 and the method of forming the lower shielding block 10).

(Configuration-shielding wall-details of shielding wall configuration-details of shielding block configuration-lower shielding block)
Next, among the details of the configuration of the shielding block 80, the details of the configuration of the lower shielding block 10 will be described. 5A and 5B are diagrams illustrating the lower shielding block 10, in which FIG. 5A is a perspective view and FIG. 5B is a cross-sectional view taken along the line CC. The lower shielding block 10 can be manufactured in any shape, method, and material unless otherwise specified.

  In the embodiment, the lower-stage shielding block 10 is a first shielding block located below the middle-stage shielding block 20. As shown in FIG. 5, the lower-stage shielding block body 11 and the lower-stage shielding block body 11 And a lower-stage convex portion 12 provided on the upper surface.

  The lower shield block body 11 is a basic structure of the lower shield block 10. As shown in FIG. 5, the lower shielding block main body 11 is configured in substantially the same manner as the middle shielding block 30, but the lower surface of the lower shielding block main body 11 is devised as follows. . That is, the lower surface of the lower shielding block main body 11 is formed so as to correspond to the installation surface 3, and specifically, the entire lower surface is formed in a substantially flat shape. Thereby, the whole lower surface of the lower stage side shielding block main body 11 can be contact | abutted to the installation surface 3, and the shielding wall 2 can be installed stably. The above-described “lower shielding block body 11” corresponds to the “first shielding block body” in the claims.

  The lower-side convex portion 12 is a convex portion that fits into the middle-stage concave portion 33 of the middle-stage shielding block 20, and has substantially the same configuration as the middle-stage convex portion 32.

(Configuration-shielding wall-details of shielding wall configuration-details of shielding block configuration-upper shielding block)
Next, among the details of the configuration of the shielding block 80, the details of the configuration of the upper shielding block 70 will be described. 6A and 6B are diagrams showing the upper shielding block 70, where FIG. 6A is a perspective view and FIG. 6B is a cross-sectional view taken along line DD. The upper shielding block 70 can be manufactured in any shape, method, and material unless otherwise specified.

  In the embodiment, the upper shielding block 70 is a second shielding block located above the middle shielding block 60. As shown in FIG. 6, the upper shielding block main body 71, the upper shielding block main body 71, And an upper side recess 72 provided on the lower surface.

  The upper shield block main body 71 is a basic structure of the upper shield block 70. The upper-stage shielding block main body 71 is configured in substantially the same manner as the middle-stage shielding block 30, but the upper surface of the upper-stage shielding block main body 71 is devised as follows. That is, the upper surface of the upper shielding block main body 71 is formed as a non-horizontal inclined surface, and specifically, is formed so as to be inclined downward as the entire upper surface is separated from the opening 1c. Thereby, it can prevent that water accumulates on the upper surface of the upper stage shielding block 70, and it becomes possible to further suppress deterioration of the shielding wall 2 by water immersion. The “upper shielding block main body 71” described above corresponds to the “second shielding block main body” in the claims.

  The upper-stage concave portion 72 is a concave portion that is fitted to the middle-stage convex portion 32 of the middle-stage shielding block 60 and has substantially the same configuration as the middle-stage concave portion 33.

(Configuration-shielding wall-details of the configuration of the shielding wall-details of the configuration other than the shielding block)
Returning to FIG. 2, the details of the configuration other than the shielding block 80 will be described.

  First, in the embodiment, the shielding wall 2 is installed so that the lower surface of the lower shielding block 10 is positioned below the lower end of the opening 1c. Specifically, as shown in FIG. 2, the lower shield block 10 is installed such that the lower surface thereof is substantially flush with the lower surface of the floor 1a of the building 1 located below the lower end of the opening 1c. Yes. Thereby, compared with the case where the lower surface of the lower shielding block 10 is flush with the lower end of the opening 1c, radiation can be prevented from passing through the gap between the lower surface of the lower shielding block 10 and the installation surface 3, The shielding property can be further improved.

  In the embodiment, the shielding wall 2 further includes an upper connection member 91, a lower connection member 92, and a mouth opening prevention member 93 as shown in FIGS. 1 to 3.

  Among these, the upper connection member 91 is an upper connection means for connecting the shielding wall 2 and the wall portion 1 b of the building 1. The upper connection member 91 is configured using, for example, a known metal drainage member. As shown in FIGS. 1 to 3, the upper connection member 91 includes the upper shielding block 70 and the wall portion 1 b of the building 1. Are arranged so as to be in contact with each other, and are detachably connected to the upper shielding block 70 and each of the wall portion 1b of the building 1 by a fixing tool.

  The lower connection member 92 is a lower connection means for connecting the shielding wall 2 and the installation surface 3. The lower connection member 92 is made of, for example, a known steel angle material, and is arranged so that the lower connection member 92 contacts the lower shielding block 10 and the installation surface 3. The lower shielding block 10 and the installation surface 3 are detachably connected by a fixing tool.

  Further, the mouth opening prevention member 93 is mouth opening prevention means for preventing mouth opening between the shielding blocks 10 to 70 and the adjacent shielding block 80. The mouth opening prevention member 93 is formed of, for example, a steel plate-like body, and is provided at the boundary portion of the adjacent shielding block 80 and the vicinity thereof among the portions of the left surface and the right surface of the shielding wall 2. It is detachably connected to the adjacent shielding block 80 by a fixture.

  With such a configuration, the shielding wall 2 and the building 1 and the installation surface 3 can be firmly connected by the upper connection member 91 and the lower connection member 92, and the shielding blocks 10 to 70 can be connected by the opening prevention member 93. Of these, adjacent shielding blocks 80 can be firmly connected. Therefore, when the external force of the seismic force acts on the shielding wall 2, it is possible to suppress the shaking of the shielding wall 2, and it is possible to avoid that the shielding wall 2 falls or any one of the shielding blocks 10 to 70 falls off. As for the mouth opening prevention member 93, the mouth opening prevention member 93 can be used for positioning the shielding block 80 when the shielding wall 2 is installed, and the integrity of the whole shielding wall 2 can be improved.

  Further, the shielding wall 2 as described above can shield the radiation by the first shielding surface 31a or the second shielding surface 31d of each of the shielding blocks 10 to 70, and the radiation can be prevented from passing through the shielding wall 2. Moreover, the horizontal movement of the shielding block 80 corresponding to the said convex part can be restrict | limited by fitting with the various convex part of each shielding block 10-70, and the recessed part corresponding to the said convex part, Can be avoided. Therefore, it is possible to improve the earthquake resistance while maintaining the shielding property as compared with the conventional technique (a technique in which the mating surface of the adjacent shielding blocks is a non-linear surface formed over the entire length in the width direction).

(About the action of the shielding wall)
Next, the effect | action of the shielding wall 2 comprised in this way is demonstrated.

  That is, for example, when radiation tries to pass through the shielding wall 2, the radiation is shielded by the first shielding surface 31 a or the second shielding surface 31 d of each of the shielding blocks 10 to 70. You can avoid passing.

  Further, for example, when an earthquake force acts on the shielding wall 2, the horizontal of the shielding block 80 corresponding to the convex portion by fitting each of the various convex portions of the shielding blocks 10 to 70 with the concave portion corresponding to the convex portion. Since the movement is restricted and the shaking of the shielding wall 2 is suppressed by the upper connecting member 91, the lower connecting member 92, and the mouth opening preventing member 93, either of the shielding blocks 10 to 70 falls off, or It can avoid that the shielding wall 2 falls.

  In addition, for example, when the shielding wall 2 is exposed to rainwater, if the rainwater enters the gap between the adjacent shielding blocks 80 among the shielding blocks 10 to 70, the first shielding surfaces of the shielding blocks 10 to 70, respectively. Since the rainwater flows down toward the outside of the shielding wall 2 by 31a, it is possible to suppress the rainwater from collecting on the upper surface of the shielding block 80 corresponding to the first shielding surface 31a. Further, when the rainwater falls on the upper surface of the upper shielding block 70, the rainwater flows toward the outside of the shielding wall 2 by the upper surface, so that the rainwater can be prevented from collecting on the upper surface.

(Installation method of shielding wall)
Then, the installation method of the shielding wall 2 is demonstrated.

  First, the shielding blocks 10 to 70 manufactured in a factory or the like are sequentially stacked and installed on the installation surface 3 using a known construction crane (not shown). Specifically, when an attachment hole (not shown) for attaching a suspension fitting (not shown) (not shown) is formed on the upper surface of each shielding block 80, any of the attachment holes of the shielding blocks 10 to 70 It is installed by repeating the operation of attaching the hanging bracket to the suspension bracket and hooking the hook portion of the crane on the hanging bracket and then lifting and moving the shielding block 80 to a predetermined position in this state. In this case, the opening preventing member 93 may be attached to the shielding block 80 that has been moved to the nearest each time the above operation is completed. This makes it possible to use the opening preventing member 93 for positioning the shielding block 80 to be moved next.

  After the shielding blocks 10 to 70 are installed, the lower shielding block 10 and the installation surface 3 are connected via the lower connection member 92, and the upper shielding block 70 and the wall 1b of the building 1 are connected to the upper side. The connection is made through the member 91. This completes the installation of the shielding wall 2. In addition, when removing the shielding wall 2, the shielding wall 2 can be removed by performing the procedure contrary to the procedure of the installation method of the said shielding wall 2. FIG.

(Configuration-shielding wall-other configurations)
In addition, the shielding block 80 can be configured with an arbitrary structure.

  Specifically, in the embodiment, it has been described that the number of the middle-side convex portions 32 provided in the middle-stage shielding block 30 is one, but the present invention is not limited to this. FIGS. 7A and 7B are diagrams showing a modification of the middle shielding block 30, in which FIG. 7A is a perspective view and FIG. 7B is a cross-sectional view taken along line EE. For example, the number of installed middle-stage convex portions 32 (columnar middle-stage convex portions 32 in FIG. 7) may be two or more (note that the configuration of the lower shielding block 10 and the configuration of the upper shielding block 70). The same shall apply to In this case, the number of middle-stage concave portions 33 to be installed is a number corresponding to the number of middle-stage convex portions 32 to be installed.

  In the embodiment, the middle-stage convex portion 32 of the middle-stage shielding block 30 is described as a long rectangular parallelepiped, but the present invention is not limited to this. 8A and 8B are views showing a modification of the middle shielding block 30, in which FIG. 8A is a perspective view and FIG. 8B is a cross-sectional view taken along the line FF. For example, the middle-stage convex portion 32 may be a long triangular prism (note that the same applies to the configuration of the lower shielding block 10 and the configuration of the upper shielding block 70). In this case, the middle-stage concave portion 33 is formed in a shape corresponding to the middle-stage convex portion 32.

  In the embodiment, the first shielding surface 31a and the second shielding surface 31d of the middle shielding block 30 have been described as straight slopes, but the present invention is not limited to this. FIG. 9 is a view showing a modified example of the middle shielding block 30, wherein (a) is a perspective view and (b) is a cross-sectional view taken along line GG. For example, the first shielding surface 31a and the second shielding surface 31d may be curved slopes (the same applies to the configuration of the lower shielding block 10 and the configuration of the upper shielding block 70).

  In the embodiment, the upper surface portion of the middle-stage convex portion 32 of the middle-stage shielding block 30 and the opposed portion of the middle-stage concave portion 33 facing the upper surface portion of the middle-stage convex portion 32 (ie, the upper surface portion of the middle-stage concave portion 33) However, the present invention is not limited to this. FIG. 10 is a cross-sectional view showing a modified example of the middle shielding block 30, and is a cross-sectional view corresponding to FIG. For example, at least one of the upper surface portion 32a of the middle-stage convex portion 32 and the upper surface portion 33a of the middle-stage concave portion 33 (both in FIG. 10) is a shielding surface that is not parallel to the radiation direction of the radiation. You may form as a 3rd shielding surface which is a shielding surface formed over the full length of the width direction (it is the same also about the structure of the lower stage shielding block 10, and the structure of the upper stage shielding block 70). Accordingly, radiation can be shielded by the upper surface portion 32a of the middle-stage convex portion 32 or the upper surface portion 33a of the middle-stage concave portion 33, and the upper surface portion 32a of the middle-stage convex portion 32 or the upper surface portion 33a of the middle-stage concave portion 33 is flat. Compared to the case of the shape, the shielding property can be improved.

  In the embodiment, the lower shielding block 10 and the upper shielding block 70 have been described as being configured differently from the middle shielding block 30, but the present invention is not limited thereto. FIG. 11 is a side view showing a modified example of the shielding wall 2, and is a side view corresponding to FIG. For example, the lower shielding block 10 or the upper shielding block 70 may be configured with the same configuration as the middle shielding block 30. In this case, when the lower shielding block 10 has the same configuration as the middle shielding block 30, a convex member 94 for fitting into the middle recess 33 of the lower shielding block 10 is provided on the installation surface 3. It may be provided.

(Effect of embodiment)
Thus, according to the embodiment, the first shielding block includes the first shielding block main body, and at least one convex portion provided on the upper surface of the first shielding block main body, and the second shielding block includes The second shielding block main body and at least one concave portion provided on the lower surface of the second shielding block main body, and can be fitted to the convex portion so that the horizontal movement of the convex portion is restricted by the concave portion. Since the concave portion is provided, the horizontal movement of the first shielding block can be restricted by fitting the convex portion and the concave portion, and the first shielding block can be prevented from falling off. Further, at least a part of the upper surface of the first shielding block body is formed as a first shielding surface 31a that is a first shielding surface 31a that is not parallel to the radiation direction of the radiation and is formed over the entire length of the upper surface in the width direction. Since at least a part of the lower surface of the second shielding block main body is formed as the second shielding surface 31d formed so as to correspond to the first shielding surface 31a, the first shielding surface 31a or the second shielding surface is formed. Radiation can be shielded by the surface 31d, and radiation can be prevented from passing through the shielding wall 2. Therefore, it is possible to improve the earthquake resistance while maintaining the shielding property as compared with the conventional technique (a technique in which the mating surface of the adjacent shielding blocks is a non-linear surface formed over the entire length in the width direction).

  In addition, since each of the first shielding surface 31a and the second shielding surface 31d is formed so as to be inclined downward toward the outside of the shielding wall 2, the first shielding surface 31a is directed to the outside of the shielding wall 2. Compared with the case where it forms so that it may incline upwards, it can suppress that water accumulates on the upper surface of a 1st shielding block main body, and can suppress the deterioration of the shielding wall 2 by water immersion.

  In addition, since the shielding wall 2 is installed so that the lower surface of the lower shielding block 10 is positioned below the lower end of the opening 1c, the lower surface of the lower shielding block 10 is flush with the lower end of the opening 1c. In comparison, radiation can be prevented from passing through the gap between the lower surface of the lower shielding block 10 and the installation surface 3, and the shielding performance can be further improved.

[III] Modifications to Embodiments Although the embodiments of the present invention have been described above, specific configurations and means of the present invention are within the scope of the technical idea of each invention described in the claims. Any modification and improvement can be made. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, but the present invention solves the problems not described above or the effects not described above. Can also be played. Moreover, only a part of the described problem may be solved or only a part of the described effect may be achieved.

(About shape, numerical value, structure, time series)
Regarding the constituent elements exemplified in the embodiment and the drawings, the shape, numerical value, or the structure of a plurality of constituent elements or the mutual relationship in time series may be arbitrarily modified and improved within the scope of the technical idea of the present invention. Can do.

(About shielding walls)
Although the said embodiment demonstrated that the shielding wall 2 was provided in the exterior of the building 1, not only this but it may be provided in the inside of the building 1, for example.

  Moreover, although the said embodiment demonstrated that the shielding wall 2 was installed so that the lower surface of the lower shielding block 10 might be located below the lower end of the opening part 1c, it is not restricted to this. FIG. 12 is a side view showing a modified example of the shielding wall 2, and is a side view corresponding to FIG. For example, when the lower end of the opening 1 c is flush with the installation surface 3, the opening 1 c may be installed so that a part of the shielding wall 2 is accommodated in the groove 3 a formed by excavating the installation surface 3. .

  Moreover, although the shielding wall 2 demonstrated that the shielding wall 2 was provided with the upper side connection member 91, the lower side connection member 92, and the opening prevention member 93 in the said embodiment, not only this but the upper side connection member 91 is mentioned, for example. At least one of the lower connection member 92 and the mouth opening prevention member 93 may be omitted.

(About shielding block)
In the above-described embodiment, the first shielding surface 31a and the second shielding surface 31d of the middle shielding block 30 have been described as being inclined downward toward the outside of the shielding wall 2. It may be inclined upward toward the outside of the shielding wall 2 (the same applies to the lower shielding block 10 and the upper shielding block 70).

  Moreover, in the said embodiment, although demonstrated that the reinforcement member 34 and the chamfering part 35 were provided in the intermediate | middle shielding block 30, it is not restricted to this, For example, at least any one of the reinforcement member 34 or the chamfering part 35 May be omitted (the same applies to the lower shielding block 10 and the upper shielding block 70).

  Moreover, although the said embodiment demonstrated that the some shielding block 80 was provided in the left-right 1 row, it is not restricted to this. FIG. 13 is a cross-sectional view showing a modification of the shielding wall 2 and corresponding to FIG. The plurality of shielding blocks 80 may be provided in two or more rows on the left and right. In this case, for example, it is desirable that the boundary surfaces of the shielding blocks 80 adjacent to the left and right are formed in a non-linear shape. Moreover, although the said embodiment demonstrated that the some shielding block 80 was provided in the up-and-down 1 row, it is not restricted to this, For example, you may provide in 2 or more rows.

  In the above embodiment, the upper surface of the upper shielding block main body 71 has been described as a non-horizontal inclined surface. However, the present invention is not limited thereto, and may be a flat surface, for example.

(Appendix)
The shielding wall of Supplementary Note 1 is a shielding wall for shielding radiation, and includes a plurality of shielding blocks stacked in the vertical direction. The plurality of shielding blocks include the first shielding block, A second shielding block adjacent to the first shielding block and positioned above the first shielding block, wherein the first shielding block includes a first shielding block body, and a first shielding block body. At least one or more protrusions provided on the upper surface and projecting upward, and the second shielding block includes at least one or more second shielding block main body and a lower surface of the second shielding block main body. A recess that is provided and that is recessed upward, the recess being engageable with the protrusion so that horizontal movement of the protrusion is restricted by the recess. At least a part of the upper surface of the main body is formed as a first shielding surface that is a shielding surface that is non-parallel to the radiation direction of the radiation and is formed over the entire length in the width direction of the upper surface; A second shield that is a shield surface that is formed so as to correspond to the first shield surface and at least a part of either one of the lower surfaces of the shield block main body and that can contact the first shield surface. Formed as a surface.

  The shielding wall of supplementary note 2 was formed so that each of the first shielding surface and the second shielding surface incline downward toward the outside of the shielding wall in the shielding wall of supplementary note 1.

  The shielding wall of appendix 3 is the shielding wall according to appendix 1 or 2, wherein at least one of the upper surface portion of the convex portion or the opposing portion of the concave portion facing the upper surface portion of the convex portion is irradiated with the radiation. It was formed as a third shielding surface that is a shielding surface that is not parallel to the direction and that is formed over the entire length of the portion in the width direction.

  The shielding wall according to appendix 4 is the shielding wall according to any one of appendices 1 to 3, wherein the shielding wall is installed in the vicinity of the opening, and is the shielding wall for sealing the opening. And the said shielding wall was installed so that the lower surface of the shielding block located in the lowest part among the said several shielding blocks may be located below the lower end of the said opening part.

(Additional effects)
According to the shielding wall according to attachment 1, the first shielding block includes the first shielding block main body, and at least one convex portion provided on the upper surface of the first shielding block main body, and the second shielding block. Are at least one concave portion provided on the lower surface of the second shielding block main body and the second shielding block main body, and can be fitted to the convex portion so that the horizontal movement of the convex portion is restricted by the concave portion. Since the concave portion is provided, the horizontal movement of the first shielding block can be limited by fitting the convex portion and the concave portion, and the first shielding block can be prevented from falling off. Further, at least a part of the upper surface of the first shielding block main body is formed as a first shielding surface which is a first shielding surface which is not parallel to the radiation direction of the radiation and is formed over the entire length in the width direction of the upper surface, 2 Since at least a part of the other lower surface of the shielding block body is formed as a second shielding surface formed so as to correspond to the first shielding surface, radiation is shielded by the first shielding surface or the second shielding surface. The radiation can be prevented from passing through the shielding wall. Therefore, it is possible to improve the earthquake resistance while maintaining the shielding property as compared with the conventional technique (a technique in which the mating surface of the adjacent shielding blocks is a non-linear surface formed over the entire length in the width direction).

  According to the shielding wall described in appendix 2, each of the first shielding surface and the second shielding surface is formed to be inclined downward toward the outside of the shielding wall. Compared with the case where the first shielding block body is formed so as to incline upward toward the outside, it is possible to suppress water from being accumulated on the upper surface of the first shielding block main body, and it is possible to suppress deterioration of the shielding wall due to water immersion.

  According to the shielding wall according to attachment 3, at least one of the upper surface portion of the convex portion or the opposing portion of the concave portion facing the upper surface portion of the convex portion is the third shielding surface that is not parallel to the radiation direction of radiation. Therefore, radiation can be shielded by the upper surface portion of the convex portion or the upper surface portion of the concave portion, and the upper surface portion of the convex portion or the upper surface portion of the concave portion. As compared with the case where is flat, the shielding property can be improved.

  According to the shielding wall described in appendix 4, since the shielding wall is installed so that the lower surface of the lowermost shielding block is located below the lower end of the opening, the lower surface of the lowermost shielding block is opened. Compared with the case where it is flush with the lower end of the part, it is possible to avoid the passage of radiation through the gap between the lower surface of the lowermost shielding block and the installation surface, and the shielding performance can be further improved.

DESCRIPTION OF SYMBOLS 1 Building 1a Floor part 1b Wall part 1c Opening part 1d Door 2 Shielding wall 3 Installation surface 3a Groove part 10 Shielding block, lower stage shielding block 11 Lower stage side shielding block main body 12 Lower stage side convex part 20 Shielding block, middle stage shielding block 30 Shielding block, Middle shielding block 31 Middle shielding block main body 31a First shielding surface 31b Front first shielding surface 31c Rear first shielding surface 31d Second shielding surface 31e Front second shielding surface 31f Rear second shielding surface 32 Middle projection 32a Upper surface portion 33 Middle step side concave portion 33a Upper surface portion 34 Reinforcing member 35 Chamfered portion 40 Shielding block, middle stage shielding block 50 Shielding block, middle stage shielding block 60 Shielding block, middle stage shielding block 70 Shielding block, upper stage shielding block 71 Upper stage shielding block main body 72 Upper side recess 80 Shield block 91 Upper side Connecting member 92 Lower connecting member 93 Opening preventing member 94 Convex member

Claims (4)

A shielding wall for shielding radiation, a shielding wall comprising a plurality of shielding blocks stacked in the vertical direction,
The plurality of shielding blocks are:
A first shielding block;
A second shielding block adjacent to the first shielding block and positioned above the first shielding block,
The first shielding block includes:
A first shielding block body;
And at least one or more protrusions provided on the upper surface of the first shielding block main body and projecting upward,
The second shielding block is
A second shielding block body;
At least one or more concave portions provided on the lower surface of the second shielding block main body and recessed upward, and are fitted to the convex portions so that horizontal movement of the convex portions is restricted by the concave portions. Possible recesses,
At least a part of the upper surface of the first shielding block main body is formed as a first shielding surface that is a shielding surface that is not parallel to the radiation direction of the radiation and is formed over the entire length of the upper surface in the width direction. ,
A shielding surface formed so as to correspond to the first shielding surface, at least a part of either one of the lower surfaces of the second shielding block main bodies, and a shielding surface capable of contacting the first shielding surface. Formed as a second shielding surface,
Shielding wall. Each of the first shielding surface and the second shielding surface is formed to be inclined downward toward the outside of the shielding wall.
The shielding wall according to claim 1. At least one of the upper surface portion of the convex portion or the opposing portion of the concave portion facing the upper surface portion of the convex portion is a shielding surface that is non-parallel to the radiation direction of the radiation and extends over the entire length in the width direction of the portion. Formed as a third shielding surface which is a shielding surface to be formed,
The shielding wall according to claim 1 or 2. The shielding wall installed in the vicinity of the opening, the shielding wall for sealing the opening,
The shielding wall is installed so that the lower surface of the shielding block located at the lowermost position among the plurality of shielding blocks is located below the lower end of the opening,
The shielding wall as described in any one of Claim 1 to 3.

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