CN115711053A - Fast-assembled concrete shielding chamber - Google Patents

Abstract

The invention provides a fast-assembled concrete shielding chamber which comprises a first shielding body and a second shielding body. The first shielding body is formed by assembling a first wall body, a second wall body, a partition wall body and a partition structure; two first wall bodies are arranged in parallel at intervals; the second wall body is arranged between the two first wall bodies, two ends of the second wall body are respectively connected with the two first wall bodies, the second wall body and the two first wall bodies enclose to form a shielding cavity, and an opening is formed in one side of the shielding cavity; the partition wall is arranged in the shielding cavity and used for partitioning the shielding cavity to form a shielding passage; one end of the partition structure is connected with the partition wall body, and the other end of the partition structure is arranged outside the shielding cavity; the second shielding body is positioned above the first shielding body and connected with the first shielding body. The invention provides a fast-assembled concrete shielding room, which aims to solve the problems of long construction time, low efficiency and the like of a shielding body in the prior art.

Description

Fast-assembled concrete shielding chamber

Technical Field

The invention belongs to the technical field of buildings, and particularly relates to a rapidly-assembled concrete shielding room.

Background

The shield is a special building, and an accelerator (which can generate irradiation rays) is usually arranged in the shield to sterilize and disinfect medicine packages and medical equipment. The shielding body is also provided with an operation control platform, a control cabinet and the like so as to facilitate the relevant operation of the working personnel.

In the prior art, the shielding body is generally formed by pouring reinforced concrete once, but the pouring construction period is long, the construction efficiency is low, and the practicability is poor.

Disclosure of Invention

The invention provides a fast-assembled concrete shielding room, which aims to solve the problems of long construction time and low efficiency of a shielding body in the prior art.

In order to realize the purpose, the invention adopts the technical scheme that: the utility model provides a assemble concrete shield room fast, includes:

the first shielding body is formed by assembling a first wall body, a second wall body, a partition wall body and a partition structure; two first wall bodies are arranged, and the two first wall bodies are arranged in parallel at intervals; the second wall body is arranged between the two first wall bodies, two ends of the second wall body are respectively connected with the two first wall bodies, the second wall body and the two first wall bodies enclose to form a shielding cavity, and an opening is formed in one side of the shielding cavity; the partition wall is arranged in the shielding cavity and used for partitioning the shielding cavity to form a shielding channel; one end of the partition structure is connected with the partition wall body, and the other end of the partition structure is arranged outside the shielding cavity and used for preventing the radiation rays in the shielding channel from leaking; and

the second shielding body is positioned above the first shielding body and connected with the first shielding body, and the second shielding body is provided with a containing cavity which is used for accommodating an operating table and a control cabinet.

In a possible implementation manner, a shielding channel is arranged inside the first shielding body, and the shielding channel comprises a first serpentine channel, a second serpentine channel and a sterilization channel; one end of the first serpentine channel is communicated with one end of the sterilization channel, and one end of the second serpentine channel is communicated with the other end of the sterilization channel; the first shielding body is provided with an inlet communicated with the other end of the first serpentine channel, and the first shielding body is also provided with an outlet communicated with the other end of the second serpentine channel;

wherein the first wall, the partition wall and the barrier structure enclose to form the first serpentine channel or the second serpentine channel; the two first wall bodies, the second wall body and the separating wall body are enclosed to form the sterilization channel.

In a possible implementation manner, the spacing direction of the two first walls is set to be a first direction, and the horizontal direction perpendicular to the first direction is set to be a second direction; each first wall body comprises a first masonry block and a first connecting piece; the first masonry blocks are arranged in a plurality of numbers, the first masonry blocks are sequentially arranged and connected in the second direction, the first connecting pieces are arranged in a plurality of numbers, at least two first connecting pieces are arranged on each first masonry block, and the first connecting pieces are arranged on two sides of each first masonry block in the first direction.

In one possible implementation manner, the second wall body comprises a second masonry block, a connecting masonry block and a second connecting piece; the second masonry blocks are arranged in sequence along the first direction and connected with each other, each second masonry block forms a first body, two connecting masonry blocks are arranged, the two connecting masonry blocks are respectively located at two ends of the first body and connected with two ends of the first body respectively, a plurality of second connecting pieces are arranged, at least two second connecting pieces are arranged on each second masonry block, and the second connecting pieces are arranged at two sides of each second masonry block along the second direction; at least two second connecting pieces are arranged on each connecting masonry block, and the second connecting pieces are arranged on the connecting masonry blocks at intervals.

In one possible implementation, the dividing wall body includes a third masonry block, a first end masonry block, a second end masonry block, and a third connector; the number of the third masonry blocks is multiple, the third masonry blocks are sequentially arranged and connected along the first direction, and each third masonry block forms a second body; the first end masonry block is positioned at one end of the second body and is connected with the second body; the second end masonry block is positioned at the other end of the second body and is connected with the second body; the third connecting pieces are arranged on the second body, the first end masonry blocks and the second end masonry blocks at equal intervals.

In a possible implementation manner, the partition structure includes a connection wall and a partition wall, the connection wall is disposed along the second direction, the connection wall is disposed between the partition wall and the partition wall, two ends of the connection wall are respectively connected to the partition wall and the partition wall, the partition wall is located outside the shielding cavity, and a length of the partition wall along the first direction is greater than a length of the opening along the first direction.

In a possible implementation manner, each of the first wall bodies includes a first sub-wall, a second sub-wall, and a third sub-wall, the first sub-walls are arranged along the second direction, and one end of the first sub-wall is connected to the second wall body; the second sub-wall is arranged along the first direction and is connected with one end, far away from the second wall body, of the first sub-wall, and the third sub-wall is arranged along the second direction and is connected with the first sub-wall and is connected with one end, close to the first sub-wall, of the second sub-wall.

In a possible implementation manner, the second sub-wall includes a fourth masonry block, a fifth masonry block and a fourth connecting member, the fourth masonry block is connected with the fifth masonry block in an abutting manner, the fourth connecting member is provided with a plurality of connecting pieces, and the fourth connecting members are arranged on the fourth masonry block and the fifth masonry block at intervals along the first direction.

In one possible implementation, a conveying chain is arranged in the shielding channel and is used for conveying medical supplies and equipment needing to be sterilized.

In a possible implementation, the first shield body and the second shield body are connected by a fifth connecting member.

The fast-assembled concrete shielding chamber provided by the invention has the beneficial effects that: compared with the prior art, the two first wall bodies are arranged in parallel and at intervals, the second wall body is arranged between the two first wall bodies, and the two ends of the second wall body are respectively spliced with the two first wall bodies. Two first walls and second wall enclose to close and form the shielding chamber, set up the partition wall body in the shielding chamber to the partition wall body separates the shielding chamber and forms shielding passageway, still is provided with the fender structure simultaneously, and fender structure one end links to each other with the partition wall body, and the other end sets up the outside in shielding chamber, thereby prevents that the irradiation ray in the shielding passageway from revealing. First wall body, second wall body, divider wall body and separate a shelves structure and assemble and form first shielding body, have effectively improved the construction efficiency of first shielding body, have shortened construction cycle greatly. Simultaneously, still be provided with the second shielding body in the top of first shielding body, still be provided with operation, switch board etc. so that the staff operates in the chamber that holds of second shielding body, and the practicality is good.

Drawings

Fig. 1 is a first schematic structural diagram of a fast-assembling concrete shielding room according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a fast-assembling concrete shielding chamber according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram three of the fast-assembled concrete shielding room provided in the embodiment of the present invention;

fig. 4 is a schematic structural diagram of a rapid-assembly concrete shielding chamber provided in the embodiment of the present invention.

Description of reference numerals:

10. a first shield body; 11. a first wall; 111. a first sub-wall; 1111. a first masonry block; 1112. a first connecting member; 112. a second sub-wall; 1121. a fourth masonry block; 1122. a fifth masonry block; 1123. a fourth connecting member; 113. a third sub-wall; 12. a second wall; 121. a second masonry block; 122. connecting the masonry blocks; 123. a second connecting member; 124. a transitional masonry block; 13. partitioning the wall; 131. a third masonry block; 132. a first end masonry block; 133. a second end masonry block; 134. a third connecting member; 14. a barrier structure; 141. connecting the wall body; 142. a partition wall body; 15. a shielding passage; 16. an opening; 20. a second shield body; 30. a fifth connecting member; 40. an accelerator; 50. and (4) the ground.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It should be noted that the terms "length," "width," "height," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "head," "tail," and the like, are used in an orientation or positional relationship indicated in the drawings for convenience in describing the invention and to simplify the description, but are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and are not to be construed as limiting the invention.

It should also be noted that, unless expressly specified or limited otherwise, the terms "mounted," "connected," "secured," "disposed," and the like are to be construed broadly and include, for example, fixed connections, removable connections, or integral parts thereof; can be mechanically or electrically connected; the two elements may be connected directly or indirectly through an intermediate medium, or the two elements may be connected through an intermediate medium or may be in an interactive relationship with each other. The specific meanings of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. Further, "plurality" or "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1 to 4 together, a rapid concrete assembly shelter according to the present invention will now be described. The fast-assembled concrete shielding chamber comprises a first shielding body 10 and a second shielding body 20. The first shielding body 10 is formed by assembling a first wall 11, a second wall 12, a partition wall 13 and a partition structure 14. Two first walls 11 are arranged, and the two first walls 11 are parallel and arranged at intervals. The second wall 12 is disposed between the two first walls 11, and two ends of the second wall 12 are respectively spliced with the two first walls 11. The second wall 12 and the two first walls 11 enclose a shielding cavity, and an opening 16 is formed in one side of the shielding cavity. Partition walls 13 are disposed in the shielding cavities, and the partition walls 13 are used for partitioning the shielding cavities to form shielding passages 15. The barrier structure 14 is connected to the partition wall body 13 at one end, and is disposed outside the shielding cavity at the other end for preventing the radiation rays in the shielding passage 15 from leaking. The second shield body 20 is located above the first shield body 10 and connected to the first shield body 10. The second shielding body 20 has a cavity for accommodating the console and the control cabinet.

Compared with the prior art, the rapidly-assembled concrete shielding room provided by the embodiment of the invention has the advantages that the two first walls 11 are arranged in parallel at intervals, the second wall 12 is arranged between the two first walls 11, and two ends of the second wall 12 are respectively spliced with the two first walls 11. The two first walls 11 and the second wall 12 enclose to form a shielding cavity, a partition wall 13 is arranged in the shielding cavity, so that the partition wall 13 partitions the shielding cavity to form a shielding passage 15, and a barrier structure 14 is also arranged, one end of the barrier structure 14 is connected with the partition wall 13, and the other end of the barrier structure is arranged outside the shielding cavity, so that radiation rays in the shielding passage are prevented from leaking. The first shielding body 10 is formed by assembling the first wall body 11, the second wall body 12, the partition wall body 13 and the partition structure 14, so that the construction efficiency of the first shielding body 10 is effectively improved, and the construction period is greatly shortened. Meanwhile, a second shielding body 20 is further arranged above the first shielding body 10, and an operation cabinet, a control cabinet and the like are further arranged in the accommodating cavity of the second shielding body 20 so that the operation can be conveniently carried out by a worker, so that the practicability is good.

Note that the accelerator 40 is mounted on the second shield body 20.

In some embodiments, referring to fig. 3, the first shielding body 10 is provided with a shielding passage 15 therein. The shielding path 15 includes a first serpentine path, a second serpentine path, and a sterilization path. One end of the first serpentine channel is communicated with one end of the sterilization channel, and one end of the second serpentine channel is communicated with the other end of the sterilization channel. The first shielding body 10 is provided with an inlet communicated with the other end of the first serpentine channel, and the first shielding body 10 is further provided with an outlet communicated with the other end of the second serpentine channel. Wherein, a first wall body 11, a dividing wall body 13 and a barrier structure 14 enclose to form a first serpentine channel or a second serpentine channel. The two first walls 11, the second wall 12 and the partition wall 13 enclose a sterilization channel.

In this embodiment, a shielding channel 15 is disposed inside the first shielding body 10, and the shielding channel 15 includes a first serpentine channel, a second serpentine channel, and a sterilization channel. Wherein one end of the first serpentine channel is in communication with one end of the sterilization channel and one end of the second serpentine channel is in communication with the other end of the sterilization channel, such that the first serpentine channel, the second serpentine channel, and the sterilization channel form a continuous shielding channel 15. And still be equipped with the import with first serpentine passageway other end intercommunication on the first shielding body 10 to and the export with the intercommunication of second serpentine passageway other end, thereby medical supplies and the equipment that need disinfection and isolation get into shielding passageway 15 from the import, through disinfection and isolation processing back, come out from the export again, import and export set up respectively in first serpentine passageway and second serpentine passageway keep away from the one end of sterilizing the passageway, thereby avoid the irradiation ray in shielding passageway 15 to reveal. Specifically, a first wall 11, a dividing wall 13 and a barrier structure 14 enclose to form a first serpentine channel or a second serpentine channel. The two first walls 11, the second wall 12 and the partition wall 13 enclose to form a sterilization channel. The first serpentine channel and the second serpentine channel are respectively arranged at two sides of the sterilizing channel and are symmetrically arranged. Accelerator 40 is disposed above the sterilization tunnel.

In some embodiments, please refer to fig. 3, the spacing direction of the two first walls 11 is set as a first direction, and a horizontal direction perpendicular to the first direction is set as a second direction. Each first wall 11 includes a first masonry block 1111 and a first connector 1112. First masonry block 1111 is provided with a plurality of first masonry blocks 1111, each first masonry block 1111 is arranged and connected in sequence along the second direction, first connectors 1112 are provided with a plurality of first connectors 1112, each first masonry block 1111 is provided with at least two first connectors 1112, and each first connector 1112 is arranged on each side of first masonry block 1111 along the first direction. Optionally, each first masonry block 1111 has a first concave surface and a first convex surface, each first concave surface for abutting engagement with an adjacent first convex surface, and each first convex surface for abutting engagement with an adjacent first concave surface.

In this embodiment, each first masonry block 1111 has a first concave surface and a first convex surface, and the first masonry blocks 1111 are provided with a plurality of such that the first concave surfaces of two adjacent first masonry blocks 1111 are abutted against the first convex surfaces, and the first masonry blocks 1111 are sequentially arranged along the second direction and connected to form the first wall 11, thereby preventing the radiation rays from leaking from the first wall 11 and ensuring the shielding performance of the first wall 11. At least two first connectors 1112 are also provided on each first masonry block 1111, and first connectors 1112 are configured to connect first masonry blocks 1111 to ground 50 to enhance the shock resistance of first wall 11.

In some embodiments, referring to fig. 3, the second wall 12 includes second masonry blocks 121, connecting masonry blocks 122, and second connectors 123. The second masonry blocks 121 are provided in plurality, the second masonry blocks 121 are sequentially arranged and connected in the first direction, and the second masonry blocks 121 form a first body. The connecting masonry blocks 122 are two, and the two connecting masonry blocks 122 are located at two ends of the first body respectively and connected with two ends of the first body respectively. The second connecting members 123 are provided with a plurality of second connecting members 123, each second masonry block 121 is provided with at least two second connecting members 123, and the second connecting members 123 are respectively arranged on two sides of the second masonry block 121 along the second direction. At least two second connecting pieces 123 are arranged on each connecting masonry block 122, and the second connecting pieces 123 are arranged on the connecting masonry blocks 122 at intervals.

In this embodiment, every second masonry block 121 has second concave surface and second convex surface, and second masonry block 121 is provided with a plurality ofly to the second concave surface of two adjacent second masonry blocks 121 links to each other with the butt of second convex surface, and each second masonry block 121 is arranged in proper order along the first direction and is linked to each other to form first body, and then avoids the irradiation ray to reveal from second wall 12, guarantees the shielding property of second wall 12. Two connecting masonry blocks 122 are further arranged at two ends of the first body, and the two connecting masonry blocks 122 are used for connecting the second wall body 12 and the two first wall bodies 11 together. Each second masonry block 121 is further provided with at least two second connecting members 123, the second connecting members 123 are used for connecting the second masonry blocks 121 with the ground 50, each connecting masonry block 122 is provided with at least two second connecting members 123, the second connecting members 123 are arranged on the connecting masonry blocks 122 at intervals, and the second connecting members 123 are used for connecting the connecting masonry blocks 122 with the ground 50, so that the shock resistance of the second wall 12 is enhanced.

In the above embodiment, the first body further includes the transition masonry block 124, the transition masonry block 124 has two fifth convex surfaces, the fifth convex surfaces are matched with the second concave surfaces, and the fifth convex surfaces are abutted and connected with the second concave surfaces. One side of the transition masonry block 124 is connected with the second masonry block 121, and the other side is connected with the connecting masonry block 122, so that the connection of the connecting masonry block 122 and the first body is ensured.

In some embodiments, referring to fig. 3, the dividing wall 13 includes third masonry blocks 131, first end masonry blocks 132, second end masonry blocks 133, and third connectors 134. The third masonry blocks 131 are arranged in plurality, the third masonry blocks 131 are sequentially arranged and connected along the first direction, and the third masonry blocks 131 form a second body. A first end masonry block 132 is positioned at one end of the second body and is connected to the second body. A second end masonry block 133 is located at the other end of the second body and is connected to the second body. The third connecting members 134 are provided in plurality, and the third connecting members 134 are uniformly spaced apart from each other on the second body, the first end masonry block 132, and the second end masonry block 133.

In this embodiment, each third masonry block 131 has a third concave surface and a third convex surface, and the third masonry blocks 131 are provided in plurality, so that the third concave surfaces of two adjacent third masonry blocks 131 are connected to the third convex surfaces in an abutting manner, and the third masonry blocks 131 are sequentially arranged along the first direction and connected to form a second body, thereby preventing irradiation rays from leaking from the partition wall body 13, and ensuring the shielding performance of the partition wall body 13. Still be provided with first end at the both ends of second body and build piece 132 and second end and build piece 133 by laying bricks or stones, be provided with the fourth concave surface on the first end builds piece 132 by laying bricks or stones, fourth concave surface and third convex surface adaptation, and the fourth concave surface and third convex surface butt and link to each other. And a fourth convex surface is arranged on the second end masonry block 133, the fourth convex surface is matched with the third concave surface, and the fourth convex surface is abutted against and connected with the third concave surface. A plurality of third connecting members 134 are uniformly spaced on the second body, the first end masonry blocks 132, and the second end masonry blocks 133, and each third connecting member 134 is used to connect the division wall body 13 with the ground 50, thereby enhancing the shock resistance of the division wall body 13.

In some embodiments, referring to fig. 3, the partition structure 14 includes a connecting wall 141 and a partition wall 142. The connecting wall 141 is disposed along the second direction, the connecting wall 141 is disposed between the partition wall 13 and the partition wall 142, and two ends of the connecting wall 141 are connected to the partition wall 13 and the partition wall 142, respectively. The barrier wall 142 is located outside the shielding cavity, and a length of the barrier wall 142 in the first direction is greater than a length of the opening 16 in the first direction. In this embodiment, the partition wall 142 is parallel to the partition wall 13, the partition wall 142 is disposed outside the shielding cavity, a connecting wall 141 is disposed between the partition wall 13 and the partition wall 142, two ends of the connecting wall 141 are respectively connected to the partition wall 142 and the partition wall 142, the connecting wall 141 penetrates through the opening 16, and a length of the partition wall 142 in the first direction is greater than a length of the opening 16 in the first direction, so that the partition wall 142 is used for blocking the irradiation rays leaked from the opening 16 and preventing the irradiation rays from leaking from the opening 16.

In some embodiments, referring to fig. 3, each first wall 11 includes a first sub-wall 111, a second sub-wall 112, and a third sub-wall 113. The first sub-wall 111 is disposed along the second direction, and one end of the first sub-wall 111 is connected to the second wall 12. The second sub-wall 112 is disposed along the first direction and connected to an end of the first sub-wall 111 away from the second wall 12. The third sub-wall 113 is disposed along the second direction, and the third sub-wall 113 is connected to the first sub-wall 111 and to an end of the second sub-wall 112 adjacent to the first sub-wall 111. In this embodiment, the first sub-wall 111, the second sub-wall 112, the third sub-wall 113, the barrier wall 142, the connecting wall 141, and the partition wall 13 enclose to form a first serpentine channel or a second serpentine channel, so that the structure of the shielding channel 15 is relatively complex, and radiation leakage is avoided.

In some embodiments, referring to fig. 3, second sub-wall 112 includes fourth masonry blocks 1121, fifth masonry blocks 1122, and fourth connectors 1123. The fourth masonry blocks 1121 are connected with the fifth masonry blocks 1122 in an abutting mode, a plurality of fourth connecting pieces 1123 are arranged, and the fourth connecting pieces 1123 are arranged on the fourth masonry blocks 1121 and the fifth masonry blocks 1122 at intervals in the first direction. In this embodiment, a plurality of fourth connecting members 1123 are provided on the fourth masonry blocks 1121 and the fifth masonry blocks 1122 so as to ensure the connection of the second sub-wall 112 with the ground 50.

In some embodiments, referring to fig. 1, a conveyor chain is disposed in the shielding passage 15 and is used for conveying medical supplies and equipment to be sterilized. In this embodiment, the worker can control the working state of the conveyor chain in the second shielding body 20.

In some embodiments, referring to fig. 4, the first shielding body 10 and the second shielding body 20 are connected by the fifth connecting member 30, so that the connection between the first shielding body 10 and the second shielding body 20 is more stable.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. Assemble concrete shield room fast, its characterized in that includes:

the first shielding body is formed by assembling a first wall body, a second wall body, a partition wall body and a partition structure; the number of the first wall bodies is two, and the two first wall bodies are arranged in parallel at intervals; the second wall body is arranged between the two first wall bodies, two ends of the second wall body are respectively spliced with the two first wall bodies, the second wall body and the two first wall bodies enclose to form a shielding cavity, and an opening is formed in one side of the shielding cavity; the partition wall is arranged in the shielding cavity and used for partitioning the shielding cavity to form a shielding channel; one end of the partition structure is connected with the partition wall body, and the other end of the partition structure is arranged outside the shielding cavity and used for preventing the radiation rays in the shielding channel from leaking; and

the second shielding body is positioned above the first shielding body and connected with the first shielding body, and the second shielding body is provided with a containing cavity which is used for accommodating an operating table and a control cabinet.

2. The rapid-assembling concrete shielding chamber of claim 1, wherein a shielding channel is arranged inside the first shielding body, and the shielding channel comprises a first serpentine channel, a second serpentine channel and a sterilization channel; one end of the first serpentine channel is communicated with one end of the sterilization channel, and one end of the second serpentine channel is communicated with the other end of the sterilization channel; the first shielding body is provided with an inlet communicated with the other end of the first serpentine channel, and the first shielding body is also provided with an outlet communicated with the other end of the second serpentine channel;

wherein the first wall, the partition wall and the barrier structure enclose to form the first serpentine channel or the second serpentine channel; the two first wall bodies, the second wall body and the separating wall body are enclosed to form the sterilization channel.

3. The rapid-assembling concrete screened room of claim 2, wherein the spacing direction of the two first walls is set as a first direction, and the horizontal direction perpendicular to the first direction is set as a second direction; each first wall body comprises a first masonry block and a first connecting piece; the first masonry blocks are arranged in a plurality, the first masonry blocks are sequentially arranged and connected in the second direction, the first connecting pieces are arranged in a plurality, at least two first connecting pieces are arranged on each first masonry block, and the first connecting pieces are arranged on two sides of each first masonry block in the first direction.

4. The rapid erectable concrete screened room of claim 3, wherein said second wall comprises second masonry blocks, connecting masonry blocks and second connectors; the second masonry blocks are arranged in sequence along the first direction and connected with each other, each second masonry block forms a first body, two connecting masonry blocks are arranged, the two connecting masonry blocks are respectively located at two ends of the first body and connected with two ends of the first body respectively, a plurality of second connecting pieces are arranged, at least two second connecting pieces are arranged on each second masonry block, and the second connecting pieces are arranged at two sides of each second masonry block along the second direction; at least two second connecting pieces are arranged on each connecting masonry block, and the second connecting pieces are arranged on the connecting masonry blocks at intervals.

5. The rapid erectable concrete screened room of claim 4, wherein said dividing wall includes a third masonry block, a first end masonry block, a second end masonry block and a third connector; the number of the third masonry blocks is multiple, the third masonry blocks are sequentially arranged and connected along the first direction, and each third masonry block forms a second body; the first end masonry block is positioned at one end of the second body and is connected with the second body; the second end masonry block is positioned at the other end of the second body and is connected with the second body; the third connecting pieces are arranged in a plurality, and the third connecting pieces are evenly arranged on the second body, the first end masonry block and the second end masonry block at intervals.

6. The rapid concrete assembling shielding room according to claim 3, wherein the partition structure comprises a connecting wall and a partition wall, the connecting wall is disposed along the second direction, the connecting wall is disposed between the partition wall and the partition wall, two ends of the connecting wall are respectively connected to the partition wall and the partition wall, the partition wall is located outside the shielding cavity, and the length of the partition wall along the first direction is greater than the length of the opening along the first direction.

7. The rapid-erectable concrete screened room of claim 3, wherein each of said first walls comprises a first sub-wall, a second sub-wall and a third sub-wall, said first sub-wall being disposed along said second direction, said first sub-wall being connected at one end to said second wall; the second sub-wall is arranged along the first direction and is connected with one end, far away from the second wall body, of the first sub-wall, and the third sub-wall is arranged along the second direction and is connected with the first sub-wall and is connected with one end, close to the first sub-wall, of the second sub-wall.

8. The rapid concrete assembled shielding chamber according to claim 7, wherein the second sub-wall includes a fourth masonry block, a fifth masonry block and a plurality of fourth connecting members, the fourth masonry block is connected to the fifth masonry block in an abutting manner, and the fourth connecting members are provided at intervals along the first direction on the fourth masonry block and the fifth masonry block.

9. The rapid-assembling concrete screened room of claim 1, wherein a transmission chain is arranged in the screened passage, and the transmission chain is used for transmitting medical supplies and equipment which need to be disinfected and sterilized.

10. The rapid-erectable concrete screened room of claim 1, wherein said first screened body and said second screened body are connected by a fifth connector.

Images