CN212428218U - Mobile detection laboratory - Google Patents

Abstract

The utility model discloses a mobile detection laboratory, include: the experiment cabin and the buffer room; the experiment cabin comprises: the experiment cabin body and the experiment cabin negative pressure filtering system are arranged in the experiment cabin body; the buffer room includes: the buffer cabin body, the first cabin door, the second cabin door and the buffer room negative pressure filtering system; the first cabin door is arranged at the inlet of the buffer cabin body; the second cabin door is arranged between the outlet of the buffer cabin body and the inlet of the experiment cabin body; the buffer chamber negative pressure filtering system is arranged in the buffer chamber body, and the negative pressure of the experiment chamber negative pressure filtering system is larger than that of the buffer chamber negative pressure filtering system. In this scheme, the negative pressure of experiment cabin is greater than the negative pressure between the buffering, and the personnel get into the buffering room through first hatch door earlier when cominging in and going out the experiment cabin moreover, and rethread second hatch door gets into the experiment cabin, and therefore, effectively solved the experiment cabin directly with the outer intercommunication of car cause the problem of experiment cabin pollution to in order to guarantee the cleanliness factor of experiment cabin.

Description

Mobile detection laboratory

Technical Field

The utility model relates to an infectious disease detects technical field, in particular to remove and detect laboratory.

Background

When a major epidemic situation occurs, or a community outbreak group epidemic situation occurs, and the situation that an external epidemic situation is input from a border port is prevented, the mobile detection laboratory can directly arrive at the site for sampling detection and issue a detection result report, so that dangerous samples are not required to be transported midway, and the sample leakage propagation caused by the transportation of the samples or the further propagation of viruses caused by the mass flow of personnel is avoided.

However, in the existing mobile detection laboratory, no buffer space is designed outside the experiment chamber, and the experiment chamber is easily polluted when people go in and out of the experiment chamber; in addition, in the manual sampling link of the existing mobile detection laboratory, the problems that a sampler is easily cross-infected and the operation is complicated and the efficiency is low exist.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a remove and detect laboratory can effectively solve the direct problem that causes the experiment cabin to pollute with the outer intercommunication of car of experiment cabin to guarantee the cleanliness factor in experiment cabin.

In order to achieve the above object, the utility model provides a following technical scheme:

a mobile detection laboratory, comprising: the experiment cabin and the buffer room;

the experiment cabin comprises: the experiment cabin body and the experiment cabin negative pressure filtering system are arranged in the experiment cabin body;

the buffer room comprises: the buffer cabin body, the first cabin door, the second cabin door and the buffer room negative pressure filtering system;

the first cabin door is arranged at the inlet of the buffer cabin body; the second cabin door is arranged between the outlet of the buffer cabin body and the inlet of the experiment cabin body; the buffer room negative pressure filtering system is arranged in the buffer cabin body, and the negative pressure of the experiment cabin negative pressure filtering system is greater than that of the buffer room negative pressure filtering system.

Preferably, the buffer room further comprises: and the ultraviolet sterilization equipment is arranged in the buffer cabin body.

Preferably, the experimental chamber further comprises: the sampling part and the detection part are arranged in the experimental cabin body;

the buffer room is positioned at the outer side of the inlet of the experiment cabin body; the sampling part is positioned at the first side of the experiment cabin and is close to the inlet of the experiment cabin; the detection part is positioned at the second side of the experiment cabin and is far away from the inlet of the experiment cabin.

Preferably, the sampling part and the detection part are respectively positioned at the left side and the right side of the experiment cabin.

Preferably, the sampling part includes: and the glove box is arranged on the side wall of the experiment cabin and communicated with the inside of the experiment cabin.

Preferably, the glove box comprises:

a box body; the outer side wall of the box body is made of transparent glass and is provided with a hand stretching opening;

set up in the outside of lateral wall, and sealing connection in stretch out the silica gel gloves of hand mouth.

Preferably, the experimental chamber further comprises: and the storage frames are arranged on the outer side of the experiment cabin body and positioned at two ends of the glove box.

Preferably, the sampling part includes: the robot sampling part and the manual sampling part.

Preferably, the robot collection part is located in the middle of the first side of the experimental cabin, and the manual sampling parts are respectively located on the front side and the rear side of the robot collection part.

Preferably, the experimental chamber further comprises: the biological safety cabinet is arranged in the experiment cabin body;

the robot acquisition part is arranged in the biological safety cabinet.

According to the technical scheme, the utility model provides an in the removal detection laboratory, the negative pressure of experiment cabin is greater than the negative pressure between the buffering, and personnel get into the buffering through first hatch door earlier when come in and go out the experiment cabin moreover between, rethread second hatch door gets into the experiment cabin, so, has effectively solved the problem that the experiment cabin directly leads to the fact the experiment cabin to pollute with the outer intercommunication of car to in order to guarantee the cleanliness factor of experiment cabin.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a top view of a mobile testing laboratory according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a mobile testing laboratory according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a glove box according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a biosafety cabinet according to an embodiment of the present invention.

Wherein 100 is an experiment chamber, 110 is an artificial sampling area, 120 is a biological safety cabinet, 121 is a sampling port, 122 is an inactivation instrument, 123 is a throat swab pipe frame, 124 is a vortex oscillator, 125 is a preservation liquid pipe clamp, 130 is a chip system analyzer for rapid detection of common respiratory pathogens, 140 is a computer, 150 is a seat, 160 is a sampling robot, 170 is a glove box, 171 is a transparent window, 172 is a silica gel glove, 180 is a water tank, and 190 is a storage frame; 200 is a buffer room, 210 is a first door, 220 is a second door, 230 is a buffer room negative pressure filtering system, 240 is ultraviolet sterilizing equipment, and 250 is a vehicle-mounted refrigerator.

Detailed Description

The utility model discloses a remove and detect laboratory, wherein, between the buffering has been designed in the experiment cabin outside, for taking independent negative pressure filtration system and ultraviolet sterilization equipment's airtight space between the buffering, play the effect that control polluted air current and control pressure differential, guaranteed the cleanliness factor in experiment cabin. In addition, a manual sampling area is designed, and the manual sampling area is sealed and isolated from the testee, so that the safety of a sampler and the testee is ensured.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The embodiment of the utility model provides a mobile detection laboratory, as shown in figure 1, include: the experiment cabin 100 and the buffer room 200;

the experimental chamber 100 comprises: the experiment cabin body and the experiment cabin negative pressure filtering system are arranged in the experiment cabin body;

the buffer room 200 includes: the buffer cabin body, the first door 210, the second door 220 and the buffer chamber negative pressure filtering system 230;

the first door 210 is arranged at the inlet of the buffer cabin body; the second door 220 is arranged between the outlet of the buffer cabin and the inlet of the experimental cabin; the buffer chamber negative pressure filtering system 230 is arranged in the buffer chamber body, and the negative pressure of the experiment chamber negative pressure filtering system is larger than the negative pressure of the buffer chamber negative pressure filtering system 230.

According to the technical scheme, the embodiment of the utility model provides an in the removal detection laboratory, the negative pressure of experiment cabin is greater than the negative pressure between the buffering, and personnel get into between the buffering through first hatch door earlier when the experiment cabin comes in and go out in addition, and rethread second hatch door gets into the experiment cabin, and therefore, effectively solved the experiment cabin and directly led to the fact the problem that the experiment cabin pollutes with the outer intercommunication of car to the cleanliness factor in order to guarantee the experiment cabin.

In this embodiment, as shown in fig. 1, the buffer room 200 further includes: and the ultraviolet sterilization equipment 240 is arranged in the buffer cabin body. The design of this scheme to play the effect of sterilization, prevent that personnel from bringing pollutants such as bacterium into experiment cabin 100, played the effect of controlling the contaminated air current promptly, with this cleanliness factor of having guaranteed experiment cabin 100.

In particular, the experimental chamber 100 further comprises: the sampling part and the detection part are arranged in the experimental cabin body;

as shown in fig. 1, the buffer room 200 is located at the outer side of the inlet of the experimental cabin; the sampling part is positioned at the first side of the experiment cabin and is close to the inlet of the experiment cabin; the detection part is positioned at the second side of the experiment cabin and is far away from the inlet of the experiment cabin. The functional interval of the scheme is designed so that a worker can conveniently construct a work flow according to the sequence of buffering, sampling and detecting, and the scheme has the characteristics of obvious functional partition, superior experimental route and the like.

Furthermore, the sampling part and the detection part are respectively positioned at the left side and the right side of the experiment cabin body, so that the layout interval of the sampling part and the detection part is shortened, the rapid transfer of the sample between the sampling part and the detection part is convenient to realize, and the detection efficiency of the sample is improved.

In the scheme, in order to eliminate the risk that the manual sampling is easily infected, the side wall of the experimental cabin body needs to be provided with manual sampling auxiliary equipment isolated from the outside; accordingly, as shown in fig. 2, the sampling part includes: and the glove box 170 is arranged on the side wall of the experiment cabin body and can be communicated with the inside of the experiment cabin body. The glove box 170 is isolated from the outside of the vehicle. In the scheme, the manual sampling is carried out through the glove box 170, so that the risk of cross infection of a sampler and a subject can be effectively eliminated. Of course, as shown in fig. 1, a glove box 170 is provided to the manual sampling area 110.

Specifically, in order to facilitate a sampler to view the situation outside the vehicle inside the vehicle, so as to facilitate the visual operation of the sampler, it is required that the material of the outer sidewall of the glove box 170 is transparent, and it is also required that an isolation glove for the operation of the human is arranged outside the outer sidewall; accordingly, as shown in fig. 3, the glove box 170 includes:

a box body; the outer side wall of the box body is made of transparent glass and is provided with a hand stretching opening; as shown in fig. 3, the outer side wall of the box body is a transparent window 171;

the silicone glove 172 is arranged on the outer side of the outer side wall and is connected to the hand stretching opening in a sealing manner. Wherein, the number of silica gel gloves 172 is two to both hands stretch into two silica gel gloves when artifical sampling and carry out the pharynx swab sampling to the examinee.

Further, as shown in fig. 3, the experimental chamber 100 further comprises: and the storage frames 190 are arranged at the outer side of the experiment cabin and positioned at two ends of the glove box 170. This scheme is through addding two and put thing frame 190 to in the interim deposit of collection instrument and pathogen preservation liquid, thereby serve the manual sampling better. Of course, the sample stored in the storage box 190 is transferred to the experiment chamber 100 by the sampling robot 160 disposed in the biosafety cabinet 120.

In this aspect, the sampling section includes: the robot acquisition part and the manual sampling part are used for carrying the robot acquisition throat swab system and the manual acquisition throat swab system (glove box 170) in the experimental cabin, so that the acquisition of the manual robot can be realized, the acquisition efficiency can be improved, and the diversified pathogen acquisition function is also met.

Furthermore, the robot acquisition part is positioned in the middle of the first side of the experimental cabin, and the manual sampling parts are respectively positioned on the front side and the rear side of the robot acquisition part. The manual sampling is realized by the glove box 170 mentioned above. In this scheme, robot acquisition part and artifical sampling part have adopted regional division to make the branch work clear, artifical sampling part is located robot acquisition part's front and back both sides respectively moreover, so that the sample that the sampling robot 160 through robot acquisition part will artifical the gathering shifts to the experiment under-deck.

In this embodiment, the experiment chamber 100 further comprises: a biological safety cabinet 120 arranged in the experiment cabin body;

the robot acquisition part is arranged in the biosafety cabinet 120. That is, the robot collecting part is operated in the clean biological safety cabinet 120, and the throat swab of the subject is extended out of the vehicle through the collecting port 121 for sampling, so that the sample can be effectively protected from being polluted.

The present solution is further described below with reference to specific embodiments:

the utility model discloses technical scheme:

the utility model discloses a mobile laboratory of on-spot short-term test, mobile laboratory use whole car as the carrier, divide into between experiment cabin and buffering.

All designs independent negative pressure filtration system between experiment cabin and buffering, and forms pressure differential, and the negative pressure is less than the experiment cabin negative pressure between the buffering, and personnel get into between the buffering through first hatch door earlier when cominging in and going out the experiment cabin, and the second hatch door of rethread gets into the experiment cabin, and the effectual air outside having avoided pollutes to the experiment cabin.

Carry out the collection pharynx swab system of robot and artifical collection pharynx swab system in the laboratory cabin, realize that the artificial robot gathers simultaneously, when improving collection efficiency, ensured the reliability of mobile laboratory.

The whole vehicle can be externally connected with mains supply, is simultaneously provided with a self-generating system and a storage battery, can start the self-generating system in the vehicle to supply power for electric equipment in the vehicle by combining with the electric power of the storage battery under the condition that the external mains supply cannot be connected, or has power failure when being connected with the mains supply, and can ensure the normal operation of a vehicle-mounted mobile laboratory by switching the power generating system in the vehicle through the UPS.

The experimental cabin comprises: a B2-level biological safety cabinet, a manual sampling glove box, a chip system analyzer for quickly detecting common respiratory pathogens, a computer, a negative pressure filtration system, an ultraviolet sterilization device, a parking air conditioner and a water tank.

The buffer room includes: negative pressure filtration system, ultraviolet sterilization equipment, refrigerator, folding chair, wardrobe etc. buffer room design twice hatch door, one of them hatch door can get into the experiment cabin, and the other hatch door comes in and goes out the detection car, and the effect of buffer room has been solved the experiment cabin hatch door and has been directly towards detecting the car outside, the problem of the pollution of outer air to the experiment cabin when personnel come in and go out.

As shown in fig. 4, the B2-grade biosafety cabinet is installed in the experiment chamber, is provided with negative pressure filtration, is isolated from the experiment chamber, and meets the secondary safety standard; the robot collection system designs in biological safety cabinet, the accessible biological safety cabinet sampling window stretches out the car and carries out the sampling of pharynx swab to the testee outside, simultaneously the robot (sampling robot 160) is accomplished the pharynx swab in biological safety cabinet and is put into the preservation liquid pipe, again put into the vibration in the vortex oscillator to the pharynx swab preservation liquid pipe that has the pharynx swab pathogen, then put into the inactivation appearance and carry out the pathogen inactivation, the robot collection system is operated in clean biological safety cabinet, can effectively protect not receiving the sample and originally not receive the pollution.

Design of manual sampling: as shown in fig. 2 and 3, a glove box is designed for manual sampling, the glove box is completely isolated from the outside of the vehicle and is made of transparent glass, a sampler can look outside the vehicle in the vehicle, two silica gel gloves are designed on the glove box, and one ends of the gloves are sealed on the glove box; the artificial sampling device has the advantages that when the artificial sampling is carried out, two hands stretch into the silica gel gloves, throat swab sampling can be carried out on a subject, the storage frames are designed at the two ends of the outer side of the glove box and used for temporarily storing collection tools and pathogen preservation liquid, and the risk of cross infection of the sampling person and the subject is effectively eliminated through the design of the glove box.

The utility model discloses mainly solve the problem:

1. the utility model designs the buffering room, which effectively solves the problem that the experiment chamber is directly communicated with the outside of the vehicle to cause the pollution of the experiment chamber;

2. the utility model discloses an artifical sampling of glove box, artifical robot that combines samples simultaneously, has satisfied diversified pathogen and has gathered the function.

The utility model discloses a key point and guard point:

1. the utility model designs a buffer room outside the experimental chamber, which plays the roles of controlling the polluted air flow and controlling the pressure difference, so as to ensure the cleanliness of the experimental chamber;

2. the utility model designs the manual sampling window which is isolated from the outside of the vehicle by the transparent glove box, thereby effectively eliminating the risk of cross infection of a sampler and a subject;

3. the utility model discloses a robot gathers pharynx swab function, and the robot design is in the biological safety cabinet, and accessible biological safety cabinet sampling window stretches out the car and carries out the pharynx swab sampling to the testee outward.

The utility model has the advantages that:

the utility model discloses design the buffering room outside the experiment cabin, played the effect that control polluted air current and control pressure differential to guarantee the cleanliness factor in experiment cabin. Robot sampling and artifical sampling have designed regional division, can guarantee that robot and artifical sampling go on simultaneously, when having improved detection efficiency, have also ensured the stability of mobile detection car sampling function.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A mobile testing laboratory, comprising: the experiment cabin (100) and the buffer room (200);

the experimental cabin (100) comprises: the experiment cabin body and the experiment cabin negative pressure filtering system are arranged in the experiment cabin body;

the buffer compartment (200) comprises: the buffer cabin body, the first cabin door (210), the second cabin door (220) and the buffer chamber negative pressure filtering system (230);

the first door (210) is arranged at the inlet of the buffer cabin body; the second door (220) is arranged between the outlet of the buffer cabin and the inlet of the experiment cabin; the buffer room negative pressure filtering system (230) is arranged in the buffer cabin body, and the negative pressure of the experiment cabin negative pressure filtering system is larger than that of the buffer room negative pressure filtering system (230).

2. The mobile testing laboratory of claim 1, wherein said buffer room (200) further comprises: and the ultraviolet sterilization equipment (240) is arranged in the buffer cabin body.

3. The mobile detection laboratory of claim 1, wherein said laboratory module (100) further comprises: the sampling part and the detection part are arranged in the experimental cabin body;

the buffer room (200) is positioned at the outer side of the inlet of the experimental cabin body; the sampling part is positioned at the first side of the experiment cabin and is close to the inlet of the experiment cabin; the detection part is positioned at the second side of the experiment cabin and is far away from the inlet of the experiment cabin.

4. The mobile testing laboratory of claim 3, wherein said sampling portion and said testing portion are located on the left and right sides of said test chamber body, respectively.

5. The mobile detection laboratory of claim 3, wherein the sampling section comprises: and the glove box (170) is arranged on the side wall of the experiment cabin body and is communicated with the inside of the experiment cabin body.

6. The mobile detection laboratory of claim 5, wherein said glove box (170) comprises:

a box body; the outer side wall of the box body is made of transparent glass and is provided with a hand stretching opening;

set up in the outside of lateral wall, and sealing connection in stretch out the silica gel gloves (172) of hand mouth.

7. The mobile detection laboratory of claim 6, wherein said laboratory module (100) further comprises: and the storage frames (190) are arranged on the outer side of the experiment cabin body and are positioned at two ends of the glove box (170).

8. The mobile detection laboratory of claim 3, wherein the sampling section comprises: the robot sampling part and the manual sampling part.

9. The mobile testing laboratory of claim 8, wherein said robot collecting part is located at the middle position of the first side of said test chamber, and said manual sampling parts are respectively located at the front and rear sides of said robot collecting part.

10. The mobile detection laboratory of claim 9, wherein said laboratory module (100) further comprises: a biosafety cabinet (120) disposed within the experimental chamber;

the robot acquisition part is arranged in the biological safety cabinet (120).

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