CN216587931U - Air film shelter and air film shelter laboratory - Google Patents

Abstract

The utility model belongs to the technical field of medical detection biological laboratories, and particularly relates to an air film shelter and an air film shelter laboratory, which comprise an inflatable film structure forming a room body after being inflated; the inflatable membrane structure comprises first air membrane walls at the front end and the rear end, second air membrane walls at the left side and the right side and an arched air membrane wall at the top; the first air film wall, the second air film wall and the arched air film wall are connected to define a functional space; the second air film wall comprises a first arch rib part and a second arch rib part; the first arch rib part comprises a plurality of vertical arch ribs extending along the vertical direction; the second arch rib part comprises a plurality of horizontal arch ribs extending along the horizontal direction; the first arch rib parts and the second arch rib parts are arranged in a staggered mode and are connected with each other; the first arch rib part is provided with an airflow window for air circulation; the second arch rib part is provided with a transfer window a for transferring articles; through horizontal arch rib and vertical arch rib staggered arrangement, reinforcing air film shelter stability, a plurality of air film shelter concatenations of being convenient for of level and smooth second air film wall satisfy diversified experiment demand.

Description

Air film shelter and air film shelter laboratory

Technical Field

The utility model belongs to the technical field of medical detection biological laboratories, and particularly relates to an air film shelter and an air film shelter laboratory.

Background

When outbreaks of viruses like the new coronavirus, which may be airborne, to prevent local medical resources from being overwhelmed by the extrusion, the medical department needs to quickly bring up medical resource assistance from the off-site, including the PCR laboratory for medical testing. The existing PCR laboratory is generally located in fixed buildings such as hospitals and research institutes, the structure and the function of the existing PCR laboratory are fixed in a partition mode, and the existing PCR laboratory is difficult to flexibly assemble to adapt to different actual requirements.

SUMMERY OF THE UTILITY MODEL

The utility model provides a gas film shelter laboratory capable of being flexibly spliced and assembled, and diversified experimental task requirements are met by splicing and assembling a single gas film shelter.

A gas film shelter comprises an inflatable film structure which forms a room body after being inflated;

the inflatable membrane structure comprises first air membrane walls at the front end and the rear end, second air membrane walls at the left side and the right side, and an arched air membrane wall at the top; the first air film wall, the second air film wall and the arched air film wall are connected to define a functional space;

the second air film wall comprises a first arch rib part and a second arch rib part; the first arch rib part comprises a plurality of vertical arch ribs extending along the vertical direction; the second arch rib part comprises a plurality of horizontal arch ribs extending along the horizontal direction; the first arch rib parts and the second arch rib parts are arranged in a staggered mode and are connected with each other;

the first arch rib part is provided with an airflow window for air circulation; and the second arch rib part is provided with a transfer window a for transferring articles.

Through the mode that adopts horizontal arch rib and vertical arch rib staggered arrangement on the second air film wall, the stability of reinforcing air film shelter, the concatenation of a plurality of air film shelter of being convenient for of the second air film wall that levels simultaneously, and then satisfy diversified experiment demand.

Furthermore, the functional space comprises a buffer area a, a buffer area b and a functional area, wherein magnetic suction doors are arranged between the buffer area a and the buffer area b and between the buffer area b and the functional area.

Through carrying out the subregion design to the functional space, set up independent buffer a and buffer b, guarantee that the environment of functional area is clean.

Furthermore, the first air film wall comprises an air film front wall and an air film rear wall, the air film front wall is connected with the outside and the buffer area a, and the air film rear wall is connected with the functional area and the outside.

The buffer area a is connected to the inlet of the front wall of the air film, so that the air film can enter the buffer area a to sterilize the air film, and the cleanness of the functional area is guaranteed.

Further, an inlet is formed in the front wall of the air film; and a primary-secondary door for outlet, a transmission window b for transmitting experimental garbage and an air inlet and exhaust system are arranged on the air film rear wall, and the air inlet and exhaust system comprises a filtering device for filtering air entering and discharging the cabin body.

The cleanliness of the air inside and outside the air film shelter body is ensured by filtering the air entering and exhausting the air film shelter.

A gas film shelter laboratory comprises at least two gas film shelters; the second air film walls of the adjacent air film square cabins are mutually attached, and the airflow windows and the delivery windows a of the adjacent air film square cabins are respectively aligned one by one.

The air film square cabins are spliced and combined for use, so that the treatment efficiency of the experimental sample can be improved, and diversified experimental requirements can be met; and meanwhile, the functional areas of the air film shelter laboratories are physically separated through the transfer windows a, so that the use safety of the shelter laboratories is improved.

A gas film shelter laboratory comprises four gas film shelters; the four air film square cabins are sequentially arranged, and the second air film walls of the adjacent air film square cabins are mutually attached; the airflow windows and the delivery windows a of the adjacent air film square cabins are aligned one by one.

The four air film square cabins are spliced and combined for use, so that the treatment efficiency of the experimental sample is improved, and diversified experimental requirements are met; and meanwhile, the functional areas of the air film shelter laboratories are physically separated through the transfer windows a, so that the use safety of the shelter laboratories is improved.

Furthermore, a first functional space, a second functional space, a third functional space and a fourth functional space are sequentially defined by the four air film square cabins according to the arrangement sequence;

the functional area of the first functional space is a reagent preparation room for preparing and subpackaging stored reagents;

the functional area of the second functional space is a sample sorting room and is used for storing experimental samples;

the functional area of the second functional space is a sample preparation area and is used for extracting and detecting an experimental sample;

the functional area of the second functional space is an amplification area and is used for an experimental sample amplification detection area.

Furthermore, connecting channels are arranged among the buffer areas a of the four air film square cabins and are used for personnel to flow.

Furthermore, the inlets of the reagent preparation room and the amplification area are primary and secondary doors, and the inlets of the sample preparation room and the sample preparation area are magnetic doors.

Further, the reagent preparation room is under positive pressure, and the sample preparation room, the sample preparation area and the amplification area are under negative pressure.

Through setting up different atmospheric pressure, effectively prevent the pollution of air film aerosol, guarantee experimenter's safety.

The utility model has the beneficial effects that:

according to the utility model, the air film walls of the single air film shelter are arranged in a staggered manner by adopting the transverse arch ribs and the vertical arch ribs, so that the stability of the air film shelter is enhanced, the smooth air film shelter walls are convenient for splicing a plurality of air film shelters, and further the diversified experiment requirements are met; meanwhile, an airflow window and a transfer window are arranged to facilitate gas circulation and transfer of an experimental sample; the independent buffer area a and the independent buffer area b are arranged for the independent air film shelter, and an independent air inlet and exhaust system is arranged at the same time, so that the experimental safety of the functional area is enhanced; the connecting channel is arranged in the buffer area a, so that experimenters can conveniently flow among a plurality of air film square cabins; the air film shelter laboratory has strong independence and maneuverability, can flexibly combine a plurality of air film shelters, and simultaneously ensures the convenience of quickly assembling and disassembling the air film shelter.

Drawings

FIG. 1 is a schematic perspective view of a view A of a gas film shelter;

FIG. 2 is a schematic perspective view of a view B of the air film shelter;

FIG. 3 is a schematic plan design view of a gas film shelter;

FIG. 4 is a schematic perspective view of a gas film shelter laboratory;

fig. 5 is a schematic plan design of a gas film shelter laboratory.

Reference numerals:

1. a first air film wall; 2. a second gas film wall; 3. an arched air film wall; 4. a first rib portion; 5. a second rib portion; 6. a gas film front wall; 7. a gas film rear wall; 8. a buffer area a; 9. a buffer area b; 10. a functional region; 11. an airflow window; 12. a transmission window a; 13. a transmission window b; 14. an air intake and exhaust system; 15. a primary and secondary door; 16. a magnetic door; 17. a connecting channel; 18. a reagent preparation room; 19. a sample sorting room; 20. a sample preparation zone; 21. an amplification zone.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art. Furthermore, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

FIGS. 1-3 illustrate a gas film shelter comprising an inflatable film structure that is inflated to form a roof;

the inflatable membrane structure comprises first air membrane walls 1 at the front end and the rear end, second air membrane walls 2 at the left side and the right side, and an arched air membrane wall 3 at the top; the first air film wall 1, the second air film wall 2 and the arched air film wall 3 are connected to define a functional space;

the second air film wall 2 comprises a first arch rib part 4 and a second arch rib part 5; the first arch rib portion 4 includes a plurality of vertical arch ribs extending in the vertical direction; the second rib portion 5 includes a plurality of horizontal ribs extending in the horizontal direction; the first arch rib parts 4 and the second arch rib parts 5 are arranged in a staggered mode and are connected with each other;

the first arch rib part 4 is provided with an airflow window 11 for air circulation; the second rib portion 5 is provided with a transfer window a12 for transferring articles.

Through the mode that adopts horizontal arch rib and vertical arch rib staggered arrangement on second air film wall 2, the stability of reinforcing air film shelter, the concatenation in a plurality of air film shelter of being convenient for of level and smooth second air film wall 2 simultaneously, and then satisfy diversified experiment demand.

Specifically, the first air film wall 1 includes an air film front wall 6 and an air film rear wall 7; the functional area 10 comprises a buffer area a8, a buffer area b9 and the functional area 10, and the safety of the interior of the air film shelter is ensured through independent partition design; an inlet is arranged on the air film front wall 6 and is connected with the outside and a buffer area a8, a magnetic door 16 is arranged between a buffer area a8 and a buffer area b9, and a magnetic door 16 is arranged between a buffer area b9 and the functional area 10; the functional area 10 is connected with the outside through an outlet arranged on the air film rear wall 7, the outlet is provided with a primary-secondary door 15, and each area is independently divided by arranging various doors, so that the experimental safety of the functional area 10 is ensured; the air film rear wall 7 is further provided with a transfer window b13 and an air inlet and exhaust system 14, the transfer window b13 is used for conveying experimental garbage generated by the functional area 10 to the outside, and the air inlet and exhaust system 14 comprises a filtering device used for filtering other air entering and exhausting the air film shelter, so that the cleanliness of the air inside and outside the air film shelter body is ensured.

Particularly, the air film shelter adopts a self-cleaning anti-aging film, so that the regeneration of germs is inhibited, and the safety inside the air film shelter is ensured.

Particularly, the primary and secondary door is a zipper door or a magic tape door.

A gas film shelter laboratory comprises at least two gas film shelters; the second air film walls 2 of the adjacent air film square cabins are mutually attached, and the airflow windows 11 and the delivery windows a12 of the adjacent air film square cabins are respectively aligned one by one.

The air film square cabins are spliced and combined for use, so that the treatment efficiency of the experimental sample can be improved, and diversified experimental requirements can be met; meanwhile, the functional areas 10 of the air film shelter laboratories are physically separated through the transfer windows a12, so that the use safety of the shelter laboratories is improved.

Specifically, the plurality of air film compartments are provided with connecting passages 17 in the buffer area a8 for facilitating the flow of laboratory personnel.

FIGS. 4-5 illustrate a gas film shelter laboratory comprising four gas film shelters; the four air film square cabins are sequentially arranged, and the second air film walls 2 of the adjacent air film square cabins are mutually attached; the airflow windows 11 and the transfer windows a12 of adjacent air film square chambers are aligned one by one.

The four air film square cabins are spliced and combined for use, so that the treatment efficiency of the experimental sample is improved, and diversified experimental requirements are met; meanwhile, the functional areas 10 of the air film shelter laboratories are physically separated through the transfer windows a12, and the use safety of the shelter laboratories is improved.

Specifically, a first functional space, a second functional space, a third functional space and a fourth functional space are sequentially defined by the four air film square cabins according to an arrangement sequence;

the functional area 10 of the first functional space is a reagent preparation room 18 for preparing and dispensing the stored reagent;

the functional area 10 of the second functional space is a sample sorting room 19 for storing experimental samples;

the functional area 10 of the second functional space is a sample preparation area 20 for extracting and detecting an experimental sample;

the functional region 10 of the second functional space is an amplification region 21 for amplifying the detection region of the test sample.

The accuracy of each procedure step of the experiment is ensured by performing independent function limitation on the functional region 10.

Specifically, the connecting channels 17 are arranged between the buffer areas a8 of the four air film square cabins, so that the flow of experimenters is facilitated.

Specifically, the reagent preparation room 18 and the entrance of the amplification area 21 are the child-mother door 15, and the sample preparation room 19 and the entrance of the sample preparation area 20 are the magnet door 16.

In this embodiment, the reagent preparing chamber 18 is at a positive pressure, and the finishing chamber 19, the sample preparing area 20 and the amplifying area 21 are at a negative pressure.

Through setting up different atmospheric pressure, effectively prevent the pollution of air film aerosol, guarantee experimenter's safety.

In the present embodiment, the air intake and exhaust system 14 is arranged so that each cabin can be ventilated 8 times per hour.

In this embodiment, the arched air film wall 3 is 3.3-3.5 m high, and the second air film wall 2 is 2.5m high.

It should be noted that the size of the air film square cabin can be customized according to actual requirements.

The using method of the utility model comprises the following steps:

when the air film shelter is used, the air film shelter meeting the experimental requirements is moved to an open area, and air is filled into the air film shelter, so that the establishment of the independent air film shelter is realized; when the air film square cabins are connected, the connecting channels 17, the airflow windows 11 and the transfer windows a12 are aligned one by one respectively, and the connection of the air film square cabins is completed.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A gas film shelter comprises an inflatable film structure which forms a room body after being inflated; the method is characterized in that:

the inflatable membrane structure comprises first air membrane walls (1) at the front end and the rear end, second air membrane walls (2) at the left side and the right side, and an arched air membrane wall (3) at the top; the first air film wall (1), the second air film wall (2) and the arched air film wall (3) are connected to define a functional space;

the second air film wall (2) comprises a first arch rib part (4) and a second arch rib part (5); the first arch rib part (4) comprises a plurality of vertical arch ribs extending along the vertical direction; the second arch rib portion (5) comprises a plurality of horizontal arch ribs extending along the horizontal direction; the first arch rib parts (4) and the second arch rib parts (5) are arranged in a staggered mode and are connected with each other;

the first arch rib parts (4) are provided with airflow windows (11) for air circulation; the second arch rib portion (5) is provided with a delivery window a (12) for delivering articles.

2. A gas film shelter as claimed in claim 1 wherein: the functional space comprises a buffer area a (8), a buffer area b (9) and a functional area (10), wherein a magnetic suction door (16) is arranged between the buffer area a (8) and the buffer area b (9) and between the buffer area b (9) and the functional area (10).

3. A gas film shelter as claimed in claim 2 wherein: the first air film wall (1) comprises an air film front wall (6) and an air film rear wall (7), the air film front wall (6) is connected with the outside and the buffer area a (8), and the air film rear wall (7) is connected with the functional area (10) and the outside.

4. A gas film shelter as claimed in claim 3 wherein: an inlet is formed in the air film front wall (6); the air film rear wall (7) is provided with a primary and secondary door (15) for outlet, a transmission window b (13) for transmitting experimental garbage and an air inlet and exhaust system (14), and the air inlet and exhaust system (14) comprises a filtering device for filtering air entering and exhausting the cabin body.

5. A gas film shelter laboratory characterized in that: comprising at least two air film compartments as claimed in any one of claims 1 to 4; the second air film walls (2) of the adjacent air film square cabins are mutually attached, and the airflow windows (11) and the delivery windows a (12) of the adjacent air film square cabins are respectively aligned one by one.

6. A gas film shelter laboratory characterized in that: comprising four air film compartments as claimed in any one of claims 1 to 4; the four air film square cabins are sequentially arranged, and the second air film walls (2) of the adjacent air film square cabins are mutually attached; airflow windows (11) and delivery windows a (12) of adjacent air film square cabins are aligned one by one.

7. A gas film shelter laboratory according to claim 6 in which four gas film shelters in sequence define a first functional space, a second functional space, a third functional space, a fourth functional space;

the functional area (10) of the first functional space is a reagent preparation room (18) for preparing and dispensing the stored reagent;

the functional area (10) of the second functional space is a sample sorting room (19) for storing experimental samples;

the functional area (10) of the second functional space is a sample preparation area (20) used for extracting and detecting an experimental sample;

the functional area (10) of the second functional space is an amplification area (21) used for an experimental sample amplification detection area.

8. A gas film shelter laboratory as claimed in claim 7 wherein: and connecting channels (17) are arranged among the buffer areas a (8) of the four air film square cabins and are used for personnel to flow.

9. A gas film shelter laboratory as claimed in claim 7 wherein: the inlets of the reagent preparation room (18) and the amplification area (21) are primary and secondary doors (15), and the inlets of the sample sorting room (19) and the sample preparation area (20) are magnetic doors (16).

10. A gas film shelter laboratory as claimed in claim 7 wherein: the reagent preparation chamber (18) is at a positive pressure, and the sample preparation chamber (19), the sample preparation zone (20), and the amplification zone (21) are at a negative pressure.

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