EP3926113A1

EP3926113A1 - Double-side expansion cabin type mobile nucleic acid detection laboratory

Info

Publication number: EP3926113A1
Application number: EP21155667.5A
Authority: EP
Inventors: Jiancheng Qi; Zongxing ZHANG; Jinhui Wu; Ying Yi
Original assignee: Institute Of Medical Support Technology Institute Of Systems Engineering Academy Of Military Sciences
Current assignee: Institute Of Medical Support Technology Institute Of Systems Engineering Academy Of Military Sciences
Priority date: 2020-06-19
Filing date: 2021-02-08
Publication date: 2021-12-22
Anticipated expiration: 2041-02-08
Also published as: EP3926113B1; CN111576941B; CN111576941A

Abstract

The present disclosure discloses a double-side expansion cabin type mobile nucleic acid detection laboratory, including a fixed cabin, an expansion cabin, and an expansion tent. An equipment room is arranged in the fixed cabin. The expansion cabin serves as a preparation room and a PCR room. The expansion tent serves as a core workroom and a liquid preparation room. The expansion cabin and the expansion tent are separately connected to the fixed cabin. Both the expansion cabin and the expansion tent can be folded. When completely folded, the expansion cabin and the expansion tent are located in the fixed cabin. When the expansion cabin and the expansion tent are unfolded, both the expansion cabin and the expansion tent communicate with the fixed cabin, and the expansion tent is in sealed connection with the fixed cabin. The double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure may be unfolded and folded automatically, and the expansion cabin and the expansion tent are located in the fixed cabin after being folded, so the double-side expansion cabin type mobile nucleic acid detection laboratory has the advantages of reasonable functional area distribution, small size after being folded, and large operation area after being unfolded, thereby facilitating the transportation of the laboratory.

Description

TECHNICAL FIELD

The present disclosure relates to the technical field of biosafety protection equipment and peripheral supporting facilities thereof, and in particular to a double-side expansion cabin type mobile nucleic acid detection laboratory.

BACKGROUND

Global infectious disease outbreaks occur frequently. In this century, many major outbreaks, such as SARS, H5N1 avian influenza, H1N1 influenza, and H7N9 avian influenza, have successively occurred in China. Public health and safety issue has become an important factor that seriously affects people's health, economic development, and social stability in China. International threat of high-risk pathogenic microorganisms is increasing, so does the risk of imported infectious diseases in China. However, some countries have weak relevant biosafety protection capabilities and lack of biosafety facilities, which increase the threat of the high-risk pathogenic microorganisms.
Developed countries in Europe and the United States have successively developed fast-deployable mobile biosafety third-level laboratories to ensure biosafety in local and overseas missions, with efficient emergency prevention and control capabilities for epidemics. In recent years, China has developed vehicle-mounted mobile biosafety laboratories, which play an important role in microbiological detection. However, the vehicle-mounted mobile biosafety laboratories of China also expose the disadvantages: the existing mobile laboratory adopts a vehicle cabin type structure, which consists of two cabins, so it is large in size, poor in transportation convenience, and difficult to transport over long distances, thereby resulting in that it is difficult to meet the needs of rapid detection of the pathogenic microorganisms in epidemic areas. The nucleic acid detection method which is a main method for pathogenic microorganism detection currently needs to be carried out in a PCR laboratory. However, functional layouts of existing mobile laboratories are difficult to meet the requirements on PCR detection.
Therefore, how to change the present situations, in the prior art, that an expandable mobile nucleic acid detection laboratory is large in size, poor in transportation convenience, and difficult to transport over long distances, and the functional layouts do not meet the requirements of PCR detection, becomes an urgent problem to be solved by those skilled in the art.

SUMMARY

The objective of the present disclosure is to provide a double-side expansion cabin type mobile nucleic acid detection laboratory to solve the problems in the prior art, so as to facilitate the transportation and improve the convenience of vehicle-mounted mobile nucleic acid detection laboratories.
To achieve the above objective, the present disclosure provides the following technical solution: the present disclosure provides a double-side expansion cabin type mobile nucleic acid detection laboratory, including a fixed cabin, an expansion cabin, and an expansion tent; an equipment room and a central control area are arranged in the fixed cabin; the expansion cabin serves as a preparation room and a PCR room; the expansion tent serves as a core workroom and a liquid preparation room; a buffer room is arranged in each of the fixed cabin, the expansion cabin, and the expansion tent; the expansion cabin and the expansion tent are separately connected to the fixed cabin; both the expansion cabin and the expansion tent can be folded; when completely folded, the expansion cabin and the expansion tent are located in the fixed cabin; when the expansion cabin and the expansion tent are unfolded, both the expansion cabin and the expansion tent communicate with the fixed cabin; the expansion tent is in sealed connection with the fixed cabin.
Preferably, the expansion cabin includes a first base plate, a cabin body, and a bracket. The first base plate is hinged to the fixed cabin. The cabin body is connected to the first base plate. The cabin body is made of a flexible material. The bracket is connected to the first base plate and the cabin body. When a relative angle between the first base plate and the fixed cabin changes, the bracket can drive the cabin body to move.
Preferably, the first base plate is hinged to the bottom of the fixed cabin. The bracket includes first connecting rods, a second connecting rod, first long support rods, and a second long support rod. One end of the first long support rod is hinged to one end, far away from the fixed cabin, of the first base plate. The second long support rod is connected to the top, far away from the fixed cabin, of the cabin body. The other end of the first long support rod is hinged to one end of the second long support rod. One end of the first connecting rod is hinged to the top of the fixed cabin, and the other end of the first connecting rod is hinged to the first long support rod. A hinge point of the first connecting rod and the first long support rod is located between a hinge point of the first long support rod and the second long support rod and a hinge point of the first long support rod and the first base plate. The second connecting rod is connected to the top of the cabin body. One end of the second connecting rod is hinged to the second long support rod. A hinge point of the second connecting rod and the second long support rod is located between a hinge point of the second long support rod and the first long support rod and a hinge point of the second long support rod and the cabin body.
Preferably, there are two first long support rods and two first connecting rods. Both the second long support rod and the second connecting rod are U-shaped rods. The two opposite ends of the second long support rod are respectively connected to the two first long support rods. The two opposite ends of the second connecting rod are respectively connected to the two opposite ends of the second long support rod. The bottoms of the second long support rod and the second connecting rod are separately connected to the cabin body.
Preferably, the expansion tent includes a second base plate, an inner tent, an outer tent, and a telescopic skeleton. The second base plate is hinged to the fixed cabin. One end of the telescopic skeleton is connected to the fixed cabin. The inner tent is connected to the telescopic skeleton. The outer tent is arranged outside the telescopic skeleton. The inner tent is in sealed connection with the fixed cabin. The telescopic skeleton can stretch and retract. The telescopic skeleton can drive the inner tent to move in a direction far away from the fixed cabin and be tiled to the second base plate. The outer tent is detachably connected to the inner tent. Both the inner tent and the outer tent are made of a flexible material.
Preferably, the expansion tent further includes a support rail. The support rail, which is used for supporting the second base plate, is arranged at the bottom of the fixed cabin in a sliding manner.
Preferably, the second base plate is of a foldable structure. The second base plate can be pressed against the support rail. The second base plate includes two plate bodies, where one end of one of the plate bodies is hinged to the fixed cabin, and the opposite end of the plate body is hinged to the other plate body.
Preferably, the telescopic skeleton includes a plurality of sliding frames. The plurality of the sliding frames is connected through rhombus-shaped telescopic frames. The inner tent is arranged inside the sliding frames. Reciprocating movement of the sliding frames along the second base plate can drive the inner tent to fold or unfold.
Preferably, pulley wheels are arranged at the bottoms of the sliding frames. A slide rail that is adapted to the pulley wheels is arranged on the second base plate. The pulley wheels are arranged on the slide rail in a sliding manner.
Preferably, the expansion cabin and the expansion tent are respectively arranged on two opposite sides of the fixed cabin.
Compared with the prior art, the present disclosure achieves the following technical effects: the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure includes the fixed cabin, the expansion cabin, and the expansion tent. The expansion cabin and the expansion tent are separately connected to the fixed cabin. Both the expansion cabin and the expansion tent can be folded. When completely folded, the expansion cabin and the expansion tent are located in the fixed cabin. When the expansion cabin and the expansion tent are unfolded, both the expansion cabin and the expansion tent communicate with the fixed cabin. The expansion tent is in sealed connection with the fixed cabin. The equipment room and the central control area are arranged in the fixed cabin. The expansion cabin serves as the preparation room and the PCR room. The expansion tent serves as the core workroom and the liquid preparation room. The buffer room is arranged in each of the fixed cabin, the expansion cabin, and the expansion tent. According to the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure, both the expansion cabin and the expansion tent can be folded and unfolded automatically. The expansion cabin and the expansion tent are located in the fixed cabin after being folded, so the double-side expansion cabin type mobile nucleic acid detection laboratory has the advantages of small size after being folded and large operation area after being unfolded, thereby facilitating the transportation of the laboratory, and improving the flexibility and convenience of the double-side expansion cabin type mobile nucleic acid detection laboratory.

BRIEF DESCRIPTION OF THE DRAWINGS

To describe the technical solutions in the embodiments of the present disclosure or in the prior art more clearly, the following briefly describes the accompanying drawings required for describing the embodiments. Apparently, the accompanying drawings in the following description show merely some embodiments of the present disclosure, and those of ordinary skill in the art may still derive other drawings from these accompanying drawings without creative efforts.

FIG. 1 is a front-view schematic structural diagram of a double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure;
FIG. 2 is a vertical-view schematic structural diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure;
FIG. 3 is a left-view schematic structural diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure;
FIG. 4 is a right-view schematic structural diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure;
FIG. 5 is a cross-sectional schematic diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure when folded;
FIG. 6 is an internal layout diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure;
FIG. 7 is a schematic structural diagram of an expansion cabin of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure;
FIG. 8 is a schematic structural diagram of an expansion cabin in other implementation manners of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure;
FIG. 9 is a schematic structural diagram of an expansion tent of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure.

In the drawings: 1-fixed cabin; 2-expansion cabin; 3-expansion tent; 4-lifting device; 5-first base plate; 6-cabin body; 7-bracket; 701-first connecting rod; 702-second connecting rod; 703-first long support rod; 704-second long support rod; 8-second base plate; 9-inner tent; 10-outer tent; 11-telescopic skeleton; 12-support rail; 13-pulley wheel; 14-walking wheel; 15-preparation room; 16-buffer room; 17-equipment room; 18-core workroom; 19-central control area; 20-liquid preparation room; 21-PCR room.

DETAILED DESCRIPTION

The technical solutions in the embodiments of the present disclosure will be clearly and completely described herein below with reference to the accompanying drawings in the embodiments of the present disclosure. Apparently, the described embodiments are merely part rather than all of the embodiments of the present disclosure. Based on the embodiments of the present disclosure, all other embodiments obtained by those of ordinary skill in the art without creative work fall within the scope of protection of the present disclosure.
The objective of the present disclosure is to provide a double-side expansion cabin type mobile nucleic acid detection laboratory to solve the problems in the prior art, so as to facilitate the transportation and improve the convenience of the vehicle-mounted mobile nucleic acid detection laboratories .
In order to make the above objective, features, and advantages of the present disclosure more apparent and more comprehensible, the present disclosure is further described in detail below with reference to the accompanying drawings and specific implementation manners.
Please refer to FIGs. 1 to 9, where FIG. 1 is a front-view schematic structural diagram of a double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure; FIG. 2 is a vertical-view schematic structural diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure; FIG. 3 is a left-view schematic structural diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure; FIG. 4 is a right-view schematic structural diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure; FIG. 5 is a cross-sectional schematic diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure when folded; FIG. 6 is an internal layout diagram of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure; FIG. 7 is a schematic structural diagram of an expansion cabin of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure; FIG. 8 is a schematic structural diagram of an expansion cabin in other implementation manners of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure; FIG. 9 is a schematic structural diagram of an expansion tent of the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure.
The present disclosure provides a double-side expansion cabin type mobile nucleic acid detection laboratory, including a fixed cabin 1, an expansion cabin 2, and an expansion tent 3. The expansion cabin 2 and the expansion tent 3 are separately connected to the fixed cabin 1. Both the expansion cabin 2 and the expansion tent 3 can be folded. When completely folded, the expansion cabin 2 and the expansion tent 3 are located in the fixed cabin 1. When the expansion cabin 2 and the expansion tent 3 are unfolded, both the expansion cabin 2 and the expansion tent 3 communicate with the fixed cabin 1. An equipment room 17 and a central control area 19 are arranged in the fixed cabin 1. The expansion cabin 2 serves as a preparation room 15 and a PCR room 21. The expansion tent 3 serves as a core workroom 18 and a liquid preparation room 20. A buffer room 16 is arranged in each of the fixed cabin 1, the expansion cabin 2, and the expansion tent 3. The expansion tent 3 is in sealed connection with the fixed cabin 1. The expansion tent 3 is large in size after being unfolded, and serves as the core workroom 18 and the liquid preparation room 20, which increases the operation space.
According to the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure, both the expansion cabin 2 and the expansion tent 3 can be unfolded, and are located in the fixed cabin 1 after being folded, so the double-side expansion cabin type mobile nucleic acid detection laboratory has the advantages of small size after being folded and large operation area after being unfolded, thereby facilitating the transportation of the laboratory, and improving the flexibility and convenience of the double-side expansion cabin type mobile nucleic acid detection laboratory. It should be noted that, the fixed cabin 1 may be connected to a lifting device 4. The lifting device 4 can drive the fixed cabin 1 to ascend, descend, or move, so as to facilitate the movement and transportation of the fixed cabin 1.
The expansion cabin 2 includes a first base plate 5, a cabin body 6, and a bracket 7. The first base plate 5 is hinged to the fixed cabin 1. The cabin body 6 is connected to the first base plate 5. The cabin body 6 is made of a flexible material. The bracket 7 is connected to the first base plate 5 and the cabin body 6. When a relative angle between the first base plate 5 and the fixed cabin 1 changes, the bracket 7 can drive the cabin body 6 to move. The rotation of the bracket 7 can drive the flexible cabin body 6 to unfold and fold. The first base plate 5 is hinged to the fixed cabin 1. When the cabin body 6 is unfolded completely, the first base plate 5 is parallel to the ground, and when the cabin body 6 is completely folded, the first base plate 5 is flush with a side wall of the fixed cabin 1.
Specifically, the first base plate 5 is hinged to the bottom of the fixed cabin 1. The bracket 7 includes first connecting rods 701, a second connecting rod 702, first long support rods 703, and a second long support rod 704. One end of the first long support rod 703 is hinged to one end, far away from the fixed cabin 1, of the first base plate 5. The second long support rod 704 is connected to the top, far away from the fixed cabin 1, of the cabin body 6. The other end of the first long support rod 703 is hinged to one end of the second long support rod 704. One end of the first connecting rod 701 is hinged to the top of the fixed cabin 1, and the other end of the first connecting rod 701 is hinged to the first long support rod 703. A hinge point of the first connecting rod 701 and the first long support rod 703 is located between a hinge point of the first long support rod 703 and the second long support rod 704 and a hinge point of the first long support rod 703 and the first base plate 5. The second connecting rod 702 is connected to the top of the cabin body 6. One end of the second connecting rod 702 is hinged to the second long support rod 704. A hinge point of the second connecting rod 702 and the second long support rod 704 is located between a hinge point of the second long support rod 704 and the first long support rod 703 and a hinge point of the second long support rod 704 and the cabin body 6. A driving cylinder is arranged between the first base plate 5 and the fixed cabin 1. The driving cylinder pushes the first base plate 5. The first base plate 5 rotates around the fixed cabin 1 to drive the first long support rod 703 and the second long support rod 704 to rotate. The first connecting rods 701 and the second connecting rod 702 are respectively connected to the cabin body 6, the first long support rods 703 and the second long support rod 704 to drive the cabin body 6 to unfold. When the cabin body 6 is gathered, the driving cylinder drives the first base plate 5 to rotate. Under an acting force of the first base plate 5, the first long support rods 703 and the second long support rod 704 rotate and drive, together with the first connecting rods 701 and the second connecting rod 702, the flexible cabin body 6 to fold and be gathered in the fixed cabin 1. A second base plate 8 is overturned to be flush with the side surface of the fixed cabin 1.
In addition, there are two first long support rods 703 and two first connecting rods 701. Both the second long support rod 704 and the second connecting rod 702 are U-shaped rods. The two opposite ends of the second long support rod 704 are respectively connected to the two first long support rods 703. The two opposite ends of the second connecting rod 702 are respectively connected to the two opposite ends of the second long support rod 704. The bottoms of the second long support rod 704 and the second connecting rod 702 are separately connected to the cabin body 6. It should be noted here that the structure of the bracket 7 of the expansion cabin 2 of the present disclosure is not limited to the above structure. The bracket 7 shall be able to realize the folding and unfolding of the cabin body 6. In other specific implementation manners of the present disclosure, the bracket 7 is of a rhombus-shaped telescopic frame structure. The bracket 7 is connected to the top of the cabin body 6. When the second base plate 8 is overturned, the bracket 7 can drive the cabin body 6 to unfold and fold.
More specifically, the expansion tent 3 includes a second base plate 8, an inner tent 9, an outer tent 10, and a telescopic skeleton 11. The second base plate 8 is hinged to the fixed cabin 1. A driving cylinder is arranged between the second base plate 8 and the fixed cabin 1. The driving cylinder can drive the second base plate 8 to unfold. One end of the telescopic skeleton 11 is connected to the fixed cabin 1. The inner tent 9 is connected to the telescopic skeleton 11. The inner tent 9 is in sealed connection with the fixed cabin 1 to ensure the air tightness in the tent after the inner tent 9 is connected to the fixed cabin 1. The telescopic skeleton 11 can stretch and retract. The telescopic skeleton 11 can drive the inner tent 9 to move in the direction far away from the fixed cabin 1 and be tiled on the second base plate 8. After the second base plate 8 is unfolded, the telescopic skeleton 11 drives the inner tent 9 to unfold, the outer tent 10 is detachably connected to the inner tent 9. The outer tent 10 is additionally mounted after the inner tent 9 is unfolded. Both the inner tent 9 and the outer tent 10 are made of a flexible material. There is a gap between the inner tent 9 and the outer tent 10, which can achieve a heat insulating effect.
To improve the stability of the expansion tent 3, the expansion tent 3 further includes a support rail 12. The support rail 12 is arranged at the bottom of the fixed cabin 1 in a sliding manner. When the expansion tent 3 needs to be unfolded, first, the support rail 12 is pulled out. The second base plate 8 is located at the top of the support rail 12 after being unfolded. The support rail 12 can support the second base plate 8 to improve the stability of the expansion tent 3. In other specific implementation manners of the present disclosure, the expansion tent 3 may also be fixed by tent pegs and wind ropes, so as to further improve the structural strength of the expansion tent 3.
Further, to increase the use area of the expansion tent 3, the second base plate 8 is of a foldable structure. The second base plate 8 can be pressed against the support rail 12. The second base plate 8 includes two plate bodies. One end of one of the plate bodies is hinged to the fixed cabin 1. The opposite end of the plate body is hinged to the other plate body. The second base plate 8 adopts a split structure, so that the use area of the expansion tent 3 is increased without affecting the size of the laboratory after the expansion tent 3 is gathered, thereby improving the applicability of the laboratory.
In addition, the telescopic skeleton 11 includes a plurality of sliding frames. The plurality of the sliding frames is connected through rhombus-shaped telescopic frames. The inner tent 9 is arranged inside the sliding frames. Reciprocating movement of the sliding frames along the second base plate 8 can drive the inner tent 9 to fold or unfold. After the inner tent 9 is completely unfolded, the outer tent 10 is connected to the inner tent 9 for mounting, which improves the convenience in operation.
To improve the work efficiency when the telescopic skeleton 11 is unfolded and folded, pulley wheels 13 are arranged at the bottom of the sliding frames, a slide rail that is adapted to the pulley wheels 13 is arranged on the second base plate 8, which ensures the movement trajectory of the sliding frames. The pulley wheels 13 are arranged on the slide rail in a sliding manner, which prevents the dislocation of the sliding frames from affecting the work of the expansion tent 3.
Furthermore, the expansion cabin 2 and the expansion tent 3 are respectively arranged on the two opposite sides of the fixed cabin 1. The fixed cabin 1 lands onto the ground, and the expansion cabin 2 and the expansion tent 3 are folded, which improves the convenience in operation of the laboratory.
According to the double-side expansion cabin type mobile nucleic acid detection laboratory of the present disclosure, both the expansion cabin 2 and the expansion tent 3 can be unfolded, and are located in the fixed cabin 1 after being folded, so the double-side expansion cabin type mobile nucleic acid detection laboratory has the advantages of small size after being folded and large operation area after being unfolded, thereby facilitating the transportation of the laboratory, and improving the flexibility and convenience of the double-side expansion cabin type mobile nucleic acid detection laboratory. In the present specific implementation manner, the equipment room 17 and the central control area 19 are arranged in the fixed cabin 1. The expansion cabin 2 serves as the preparation room 15 and the PCR room 21. The expansion tent 3 serves as the core workroom 18 and the liquid preparation room 20. The buffer room 16 is arranged in each of the fixed cabin 1, the expansion cabin 2, and the expansion tent 3. A liftable mast is mounted outside the fixed cabin 1. A lighting device and a camera are mounted on the mast. The central control area 19 is arranged in the laboratory. A control system and a UPS are arranged in the central control area 19, where the UPS mainly supplies power to laboratory supply fans, exhaust fans, lighting, and instruments, equipment and control systems in the laboratory. In addition, a high efficiency filter is arranged at an exhaust outlet of the core workroom 18. A scanning leak detection and sampling device is arranged downstream of the high efficiency filter, which can realize in-situ leak detection of the high efficiency filter. Exhaust outlets are fitted in the buffer rooms 16, the PCR room 21, and the preparation room 15. High efficiency filters are arranged at the exhaust outlets. Exhaust pipelines are mounted in a side wall, and a downstream aerosol sampling port is mounted on a downstream pipeline of each high efficiency filter. The exhaust air of the core workroom 18, the buffer rooms 16, and the preparation room 15 is finally collected into an exhaust static pressure box. Two exhaust fans are mounted in the exhaust static pressure box. Air supply of the laboratory is supplied into each of the core workroom 18, the buffer rooms 16, the liquid preparation room 20, the PCR room 21, and the preparation room 15 after passing through a primary efficiency filter, a medium efficiency filter, an air conditioning unit, and a high efficiency filter. It should be noted that a communicating door is arranged between every two of the core workroom 18, the buffer rooms 16, the preparation room 15, and the equipment room 17. The arrangement of the communicating doors is a common method used by those skilled in the art, which will not be described in detail here.
Specific examples are applied in the present disclosure to illustrate the principle and implementation manner of the present disclosure. The description of the above embodiments is merely used to help understand the method and its core idea of the present disclosure. Meanwhile, for those of ordinary skill in the art, there will be changes in the specific implementation manner and application scope according to the idea of the present disclosure. In conclusion, the content of the present description shall not be construed as a limitation to the present disclosure.

Claims

A double-side expansion cabin type mobile nucleic acid detection laboratory, comprising a fixed cabin, an expansion cabin, and an expansion tent, wherein an equipment room and a central control area are arranged in the fixed cabin; the expansion cabin serves as a preparation room and a PCR room; the expansion tent serves as a core workroom and a liquid preparation room; a buffer room is arranged in each of the fixed cabin, the expansion cabin, and the expansion tent; the expansion cabin and the expansion tent are separately connected to the fixed cabin; both the expansion cabin and the expansion tent can be folded; when completely folded, the expansion cabin and the expansion tent are located in the fixed cabin; when the expansion cabin and the expansion tent are unfolded, both the expansion cabin and the expansion tent communicate with the fixed cabin; the expansion tent is in sealed connection with the fixed cabin.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 1, wherein the expansion cabin comprises a first base plate, a cabin body, and a bracket; the first base plate is hinged to the fixed cabin; the cabin body is connected to the first base plate; the cabin body is made of a flexible material; the bracket is connected to the first base plate and the cabin body; when a relative angle between the first base plate and the fixed cabin changes, the bracket can drive the cabin body to move.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 2, wherein the first base plate is hinged to the bottom of the fixed cabin; the bracket comprises first connecting rods, a second connecting rod, first long support rods, and a second long support rod; one end of the first long support rod is hinged to one end, far away from the fixed cabin, of the first base plate; the second long support rod is connected to the top, far away from the fixed cabin, of the cabin body; the other end of the first long support rod is hinged to one end of the second long support rod; one end of the first connecting rod is hinged to the top of the fixed cabin, and the other end of the first connecting rod is hinged to the first long support rod; a hinge point of the first connecting rod and the first long support rod is located between a hinge point of the first long support rod and the second long support rod and a hinge point of the first long support rod and the first base plate; the second connecting rod is connected to the top of the cabin body; one end of the second connecting rod is hinged to the second long support rod; a hinge point of the second connecting rod and the second long support rod is located between a hinge point of the second long support rod and the first long support rod and a hinge point of the second long support rod and the cabin body.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 3, wherein there are two first long support rods and two first connecting rods; both the second long support rod and the second connecting rod are U-shaped rods; the two opposite ends of the second long support rod are respectively connected to the two first long support rods; the two opposite ends of the second connecting rod are respectively connected to the two opposite ends of the second long support rod; the bottoms of the second long support rod and the second connecting rod are separately connected to the cabin body.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 1, wherein the expansion tent comprises a second base plate, an inner tent, an outer tent, and a telescopic skeleton; the second base plate is hinged to the fixed cabin; one end of the telescopic skeleton is connected to the fixed cabin; the inner tent is connected to the telescopic skeleton; the outer tent is arranged outside the telescopic skeleton; the inner tent is in sealed connection with the fixed cabin; the telescopic skeleton can stretch and retract; the telescopic skeleton can drive the inner tent to move in a direction far away from the fixed cabin and be tiled to the second base plate; the outer tent is detachably connected to the inner tent; both the inner tent and the outer tent are made of a flexible material.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 5, wherein the expansion tent further comprises a support rail; the support rail which is used for supporting the second base plate is arranged at the bottom of the fixed cabin in a sliding manner.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 6, wherein the second base plate is of a foldable structure; the second base plate can be pressed against the support rail; the second base plate comprises two plate bodies, wherein one end of one of the plate bodies is hinged to the fixed cabin, and the opposite end of the plate body is hinged to the other plate body.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 7, wherein the telescopic skeleton comprises a plurality of sliding frames; the plurality of the sliding frames is connected through rhombus-shaped telescopic frames; the inner tent is arranged inside the sliding frames; reciprocating movement of the sliding frames along the second base plate can drive the inner tent to fold or unfold.
The double-side expansion cabin type mobile nucleic acid detection laboratory according to claim 8, wherein pulley wheels are arranged at the bottom of the sliding frames; a slide rail that is adapted to the pulley wheels is arranged on the second base plate; the pulley wheels are arranged on the slide rail in a sliding manner.