CN116058884B

CN116058884B - Automatic control sampling equipment

Info

Publication number: CN116058884B
Application number: CN202310052311.1A
Authority: CN
Inventors: 杨威; 孙云; 陈明辉; 齐向阳; 于刚
Original assignee: Shensu Technology Suzhou Co ltd
Current assignee: Shensu Technology Suzhou Co ltd
Priority date: 2023-02-02
Filing date: 2023-02-02
Publication date: 2023-11-14
Anticipated expiration: 2043-02-02
Also published as: CN116058884A; CN117414161A; CN117426800A

Abstract

The application relates to automatic control sampling equipment, belongs to the technical field of automatic equipment, and solves the problem that pharyngeal swab collection staff is easy to be infected; the automatic control sampling equipment comprises a shell plate, a test tube bar code scanner, a display controller, a first open slot, an ultrasonic sensor, a card reader, a reciprocating motion power device, a rotation expansion device and a sampling device; 6 the shell plates are spliced into a square shell, a first shell plate is provided with a test tube bar code scanner and a display controller on the surface, a second shell plate adjacent to the first shell plate is provided with a card reader and an ultrasonic sensor on the surface, and the square shell is internally provided with the reciprocating motion power device. The distance between the person to be collected and the throat swab collection staff is 90 degrees, so that the spray of the person to be collected is prevented from flying to the throat swab collection staff, and the risk that bacteria and viruses are transmitted to the throat swab collection staff in the working process is avoided.

Description

Automatic control sampling equipment

Technical Field

The application relates to the technical field of automatic equipment, in particular to automatic control sampling equipment.

Background

The normal human isthmus is cultured with normal oral flora without pathogenic bacteria growth. Bacteria in the pharynx are all from the outside, are not pathogenic under normal conditions, but can be infected under the condition of reduced systemic or local resistance of the organism and other external factors, and the like, so that diseases are caused. Therefore, the bacteria culture of the throat swab can separate pathogenic bacteria, and is helpful for diagnosis of diphtheria, suppurative tonsillitis, acute pharyngolaryngitis and the like.

The pharyngeal portion is a place where the viruses gather more, the pharyngeal swab specimen is a medical cotton swab, a small amount of secretion is dipped from the pharyngeal portion of a human body, the sampled specimen is the pharyngeal swab specimen, and in order to detect the virus type of the respiratory diseases, the virus type can be conveniently, quickly and accurately detected through the pharyngeal swab.

In the current large environment with frequent epidemic diseases, throat swab screening is an important means for epidemic prevention and control, throat swab collection is usually operated by doctors or nurses with certain experience, large-scale screening cannot be carried out under the condition that medical staff is stressed, meanwhile, in the existing throat swab collection working personnel and collected personnel face-to-face collection method, the spray of the collected personnel is easy to directly fly to the face of the throat swab collection working personnel, in the screening process, each throat swab collection working personnel needs to carry out thousands of collection operations every day, and the infection risk of the throat swab collection working personnel is increased.

Disclosure of Invention

In view of the above, an embodiment of the present application is directed to an automatic control sampling device, which is used to solve the problems set forth in the background art.

In order to achieve the above purpose, the present application provides the following technical solutions:

an automatic control sampling device comprises a shell plate, a test tube bar code scanner, a display controller, a first open slot, an ultrasonic sensor, a card reader, a reciprocating motion power device, a rotary telescopic device and a sampling device; 6 the shell plates are spliced into a square shell, a first shell plate surface is provided with a test tube bar code scanner and a display controller, a second shell plate surface adjacent to the first shell plate is provided with a card reader and an ultrasonic sensor, the square shell is internally provided with a reciprocating motion power device, the reciprocating motion power device is connected with a rotating telescopic device, the rotating telescopic device is connected with a sampling device, and the first shell plate and the second shell plate are internally provided with first open slots for the rotating telescopic device to move.

Further, the reciprocating motion power device comprises a driving motor, an output shaft, a first rotating rod, a second rotating rod, a spur rack, a spur gear and a first transmission shaft; the driving motor is arranged on one side of the output shaft, a first rotating rod is arranged on the other side of the output shaft, the first rotating rod is connected with a second rotating rod in a rotating mode, the second rotating rod is connected with a straight rack in a rotating mode, the straight rack is meshed with a straight gear, and a first transmission shaft is arranged on one side of the straight gear.

Further, the reciprocating power device further comprises a positioning rod, a first bearing and a limiting plate; the locating rod is characterized in that a first bearing is fixed at one end of the locating rod, the first bearing is sleeved on the first transmission shaft, a pair of limiting plates are fixed in the middle of the locating rod, and the limiting plates are arranged on two sides of the straight rack.

Further, the rotary telescopic device comprises a telescopic mechanism, a driving bevel gear, a first driven bevel gear, a second transmission shaft and a third hollow transmission shaft; the two sides of the drive bevel gear are respectively hinged with a first driven bevel gear and a second driven bevel gear, a third hollow transmission shaft is arranged in the middle of the first driven bevel gear, a second transmission shaft is arranged in the middle of the second driven bevel gear, the second transmission shaft and the third hollow transmission shaft have the same rotation axis, telescopic mechanisms are arranged at the upper end parts of the second transmission shaft and the third hollow transmission shaft, and the included angle of the telescopic mechanisms at the end parts of the second transmission shaft and the third hollow transmission shaft is 90 degrees when the telescopic mechanisms are completely extended.

Further, the telescopic mechanism comprises a telescopic fixed block, an active contact fixed round rod, a passive contact sliding round rod, a second L-shaped connecting rod, a limiting insert block, a telescopic sleeve rod, a cross hinge rod and a retraction spring; the telescopic fixed block is internally provided with a first cylindrical groove for sliding a sliding round rod in a passive contact manner, the telescopic fixed block is internally provided with a second cylindrical groove perpendicular to the first cylindrical groove, the active contact fixed round rod is in contact connection with the passive contact sliding round rod, one end of the active contact fixed round rod is fixed on the shell plate, one side of the telescopic fixed block is fixed with one end of a second L-shaped connecting rod, the other end of the second L-shaped connecting rod is provided with a telescopic sleeve rod, an initial section of a fixed part of the telescopic sleeve rod is connected with a telescopic section of a telescopic end joint of the telescopic sleeve rod through a cross hinge rod, one side of the passive contact sliding round rod is fixed with a limiting insertion block for changing the shape of the cross hinge rod, and a retracting spring is arranged between two hinge parts corresponding to the upper position and the lower position of the cross hinge rod.

Further, the telescopic sleeve rod of the telescopic mechanism connected with the second transmission shaft is a 7-section telescopic sleeve rod, and the telescopic sleeve rod of the telescopic mechanism of the third hollow transmission shaft is a 2-section telescopic sleeve rod.

Further, the middle parts of the drive bevel gear, the first driven bevel gear and the second driven bevel gear are respectively provided with a second bearing seat, and the second bearing seat arranged in the middle part of the drive bevel gear is connected with the other two second bearing seats through a first L-shaped connecting rod.

Further, a disinfection device is arranged in the square shell formed by splicing the 6 shell plates, and comprises a disinfection water tank, a first infusion hose, a second infusion tube, a delayed liquid feeding device, a secondary isolation shell, a liquid spraying head and a supporting plate; the disinfection water tank is connected with 2 first infusion hoses, 2 the tip of first infusion hose all is connected with delays the liquid feeding device, 2 the delay liquid feeding device is connected with the second transfer line, 2 the second transfer line is connected with 2 isolation areas in the second level isolation casing respectively, all be equipped with the hydrojet head in 2 isolation areas in the second level isolation casing, hydrojet head in 2 isolation areas pass through respectively capillary passageway in the second level isolation casing with the second transfer line is connected, the second level isolation casing with be connected through the backup pad between the shell plate.

Further, the delay liquid feeding device comprises an arc piston cylinder, an arc piston rod, an arc loop bar, a third connecting rod, a delay spring, a one-way liquid inlet valve and a one-way liquid outlet valve; the novel hydraulic piston is characterized in that an arc piston plate is connected in the arc piston cylinder in a sliding manner, an arc piston rod is fixed on one side of the arc piston plate, an arc sleeve rod is sleeved outside the arc piston rod, a delay spring is installed in the arc sleeve rod, a third connecting rod is fixed at the end of the arc sleeve rod, and a one-way liquid inlet valve and a one-way liquid outlet valve are installed inside the arc piston cylinder.

Further, the disinfection device further comprises an ultraviolet disinfection lamp arranged in the middle of the bottom end of the square shell, and the ultraviolet disinfection lamp is lightened when the sampling device is positioned in the secondary isolation shell.

Further, a sliding cover plate for sealing the first opening groove is arranged on the surface of the shell plate.

Further, a first of the shells is surface mounted with a USB connector.

Further, a switch button is arranged on the surface of the first shell plate.

Further, a first shell plate is provided with an emergency stop reset button on the surface.

Further, the sampling device comprises a sampling machine, a shell material positioning block, a pressure sensor, a camera, a light lamp bead and a cotton swab slot; the sampling machine tip is equipped with the shell material locating piece that is used for installing disposable protective shell material, is used for installing the cotton swab slot of gathering the cotton swab, is used for discernment collection regional camera and is used for illuminating the bright lamp pearl in oral cavity, the inside pressure sensor that is used for discernment collection cotton swab pressure that is equipped with of sampling machine.

Further, an aluminum alloy frame for stabilizing the square shell structure is arranged inside the square shell.

Further, a display control panel and a control system are integrated in the display controller, and the display controller is used for controlling the running speed and the acquisition mode of the sampling equipment and collecting the acquired video information of the acquirer.

Further, the collection mode controlled by the display controller comprises ten-person collection of the cotton swab, five-person collection of the cotton swab and one-person collection of the cotton swab.

The technical scheme has at least one of the following beneficial effects:

(1) The automatic control sampling equipment has a small structure, can be placed on a plane such as an office table to perform throat swab sampling operation, is convenient for setting sampling points and evacuating, and has low cost and convenient use;

(2) According to the automatic control sampling equipment, the collected person and the pharyngeal swab collection staff are 90 degrees, so that the flying of the droplets of the collected person to the pharyngeal swab collection staff is avoided, and the risk that the pharyngeal swab collection staff is spread with bacteria and viruses in the working process is avoided;

(3) The automatic control sampling equipment has an identity recognition function, the identity of a detected person can be confirmed through the identity card reader and the camera, the occurrence of theft brushing and error brushing is avoided, and meanwhile, the detected photo and video of the detected person can be stored so as to trace the source;

(4) The cotton swab is detected by a camera in the sampling head to acquire the area, the cotton swab is controlled to automatically move to the acquisition area for acquisition, and whether the acquisition is successful or not can be judged by the oral cavity position in an image acquired by the camera and the pressure sensor, so that the pharyngeal swab acquisition does not need professional medical care training, and a non-professional can quickly go up to operate through a use instruction;

(5) The reciprocating device, the rotary telescopic device and the sampling device are arranged to enable the sampling devices of the automatic control sampling equipment to be used alternately, wherein one sampling device is provided with a disposable protective shell material and a cotton swab collecting swab by a person to be sampled and performs oral cavity sampling, and the other sampling device is provided with a device to be sampled, the device to be sampled is provided with a device to be sampled, and the device to be sampled is provided with a device to be sampled, wherein the device to be sampled is provided with a device to be sampled;

(6) According to the application, 2 acquisition devices are driven by one driving motor to perform 90-degree reciprocating motion, and meanwhile, the operation that the acquisition devices enter and exit the square shell is realized, so that the production cost of automatic control sampling equipment is reduced, and the popularization and the use are convenient;

(7) The sterilizing device is driven by the rotary telescopic device, automatically sterilizes the sampling device in the moving process of the rotary telescopic device, and ensures that the collected cotton swab sample of a sampled person is not polluted.

In the application, the technical schemes can be mutually combined to realize more preferable combination schemes. Additional features and advantages of the application will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the application. The objectives and other advantages of the application may be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

The drawings are only for purposes of illustrating particular embodiments and are not to be construed as limiting the application, like reference numerals being used to refer to like parts throughout the several views.

Fig. 1 is a schematic structural diagram of an automatic control sampling device according to the present application.

Fig. 2 is a schematic diagram of an internal structure of an automatic control sampling device according to the present application.

Fig. 3 is a schematic structural view of a reciprocating power device for automatically controlling sampling equipment according to the present application.

Fig. 4 is a schematic structural view of a rotary telescopic device of an automatic control sampling apparatus according to the present application.

Fig. 5 is a schematic structural view of a cross hinge rod of an automatic control sampling apparatus according to the present application.

Fig. 6 is a schematic structural view of a retraction spring of an automatic control sampling apparatus according to the present application.

Fig. 7 is a schematic structural view of a sterilizing apparatus for automatically controlling sampling equipment according to the present application.

Fig. 8 is a schematic structural diagram of a delayed liquid feeding device of an automatic control sampling apparatus according to the present application.

Fig. 9 is a cross-sectional view of a delayed fluid delivery device for an automatically controlled sampling apparatus according to the present application.

Fig. 10 is a schematic structural view of an active contact fixed round bar of an automatic control sampling device according to the present application.

Fig. 11 is a schematic structural diagram of a sampling device of an automatic control sampling apparatus according to the present application.

FIG. 12 is a schematic view of a disposable protective shell material sleeved outside a shell material positioning block of an automatic control sampling device.

Reference numerals:

1. the device comprises a shell plate, a test tube bar code scanner, a display controller, a USB connector, a sliding cover plate, a switch button, a scram reset button, a first open slot, an ultrasonic sensor, a card reader, a reciprocating motion power device, a rotary telescopic device, a sampling device, a sterilizing device, a disinfecting device and a cotton swab collecting device, wherein the shell plate, the test tube bar code scanner, the display controller, the USB connector, the sliding cover plate, the switch button, the scram reset button, the first open slot, the ultrasonic sensor, the card reader, the reciprocating motion power device, the rotary telescopic device, the sampling device, the sterilizing device, the disposable protective shell material and the cotton swab collecting device are arranged in sequence, and the cotton swab collecting device is arranged in sequence.

11a1, a driving motor, 11a2, an output shaft, 11a3, a first rotating rod, 11a4, a second rotating rod, 11a5, a straight rack, 11a6, a straight gear, 11a7, a positioning rod, 11a8, a first bearing, 11a9, a limiting plate and 11a10, a first transmission shaft;

12a1, 12a2, 12a3, 12b1, 12b2, 12c1, 12c2, 12d1, 12d2, 12d3, 12d4, 12d5, 12d6, 12d7, 12d8, and 12d8, retraction springs.

13a1, a sampler, 13a2, a shell material positioning block, 13a3, a camera, 13a4, a bright lamp bead and 13a5, and a cotton swab slot;

14a1, a sterilizing water tank, 14a2, a first infusion hose, 14a3, a second infusion tube, 14a4, a delay liquid delivery device, 14a5, a secondary isolation shell, 14a6, a liquid spray head, 14a7, and a support plate;

14a41, 14a42, 14a43, 14a44, 14a45, 14a third connecting rod, 14a46, 14a47, and a one-way fluid inlet valve.

Detailed Description

The following detailed description of preferred embodiments of the application is made in connection with the accompanying drawings, which form a part hereof, and together with the description of the embodiments of the application, are used to explain the principles of the application and are not intended to limit the scope of the application.

Example 1

In one embodiment of the application, an automatic control sampling device is disclosed, as shown in fig. 1 and 2, and comprises a shell plate 1, a test tube bar code scanner 2, a display controller 3, a first open slot 8, an ultrasonic sensor 9, a card reader 10, a reciprocating power device 11, a rotary telescopic device 12 and a sampling device 13;6 shell plates 1 are spliced into a square shell, a test tube bar code scanner 2 and a display controller 3 are mounted on the surface of a first shell plate 1, a card reader 10 and an ultrasonic sensor 9 are mounted on the surface of a second shell plate 1 adjacent to the first shell plate 1, a reciprocating power device 11 is mounted in the square shell, the reciprocating power device 11 is connected with a rotating telescopic device 12, the rotating telescopic device 12 is connected with a sampling device 13, and a first open slot 8 for the rotating telescopic device 12 to move is formed in each of the first shell plate 1 and the second shell plate 1.

The square shell is the shell of automatic control sampling equipment, test tube bar code scanner 2 is used for discernment test tube bar code's serial number, display controller 3 is used for showing the identity information of acquirer, test tube bar code's serial number, the image information that sampling device 13 interior camera 13a3 gathered, the function of the work of control driving motor 11a1 still is provided to the display controller simultaneously, first open slot 8 supplies sampling device 13 to stretch out and retract square shell's inside, ultrasonic sensor 9 is used for discernment testee breaks away from disposable protective housing material 15, card reader 10 is used for discernment testee's identity information, reciprocating motion power device 11 is used for driving rotation telescoping device 12 and carries out reciprocating motion, rotation telescoping device 12 is used for driving sampling device 13 90 reciprocal rotations in square shell and stretch out and retract square shell with sampling device 13 in the rotation switching-over department, sampling device 13 is used for sampling the pharyngeal of acquirer through gathering cotton swab 16.

Preferably, as shown in fig. 3, the reciprocating power means 11 includes a driving motor 11a1, an output shaft 11a2, a first rotating lever 11a3, a second rotating lever 11a4, a spur rack 11a5, a spur gear 11a6, and a first transmission shaft 11a10; the driving motor 11a1 is installed on one side of the output shaft 11a2, a first rotating rod 11a3 is installed on the other side of the output shaft 11a2, a second rotating rod 11a4 is connected to the first rotating rod 11a3 in a rotating mode, a straight toothed bar 11a5 is connected to the second rotating rod 11a4 in a rotating mode, a straight gear 11a6 is meshed with the straight toothed bar 11a5, and a first transmission shaft 11a10 is installed on one side of the straight gear 11a6.

The driving motor 11a1 drives the output shaft 11a2 to rotate, the output shaft 11a2 drives the first rotating rod 11a3 to rotate, the first rotating rod 11a3 drives one end of the second rotating rod 11a4 to rotate, the other end of the second rotating rod 11a4 reciprocates up and down under the limit of the straight rack 11a5, the straight rack 11a5 reciprocates up and down, the straight rack 11a5 drives the straight gear 11a6 to rotate forward and backward, and the straight gear 11a6 drives the first transmission shaft 11a10 to rotate forward and backward.

Preferably, the reciprocating power apparatus 11 further includes a positioning rod 11a7, a first bearing 11a8 and a limiting plate 11a9; one end of the positioning rod 11a7 is fixed with a first bearing 11a8, the first bearing 11a8 is sleeved on the first transmission shaft 11a10, a pair of limiting plates 11a9 are fixed in the middle of the positioning rod 11a7, and the limiting plates 11a9 are arranged on two sides of the straight rack 11a5.

The limiting plate 11a9 is used for limiting the straight rack 11a5, so that the straight rack 11a5 can only move up and down, the first bearing 11a8 and the limiting plate 11a9 are both fixed on the positioning rod 11a7, and the positioning rod 11a7 is used for fixing the relative positions of the first bearing 11a8 and the limiting plate 11a9.

Preferably, the rotary telescopic device 12 comprises a telescopic mechanism 12d, a drive bevel gear 12a1, a first driven bevel gear 12a2, a second driven bevel gear 12a3, a second transmission shaft 12c1 and a third hollow transmission shaft 12c2; the two sides of the drive bevel gear 12a1 are respectively hinged with a first driven bevel gear 12a2 and a second driven bevel gear 12a3, a third hollow transmission shaft 12c2 is arranged in the middle of the first driven bevel gear 12a2, a second transmission shaft 12c1 is arranged in the middle of the second driven bevel gear 12a3, the second transmission shaft 12c1 and the third hollow transmission shaft 12c2 have the same rotation axis, telescopic mechanisms 12d are arranged at the upper end parts of the second transmission shaft 12c1 and the third hollow transmission shaft 12c2, and an included angle of the telescopic mechanisms 12d at the end parts of the second transmission shaft 12c1 and the third hollow transmission shaft 12c2 is 90 degrees when the telescopic mechanisms are fully extended.

The first transmission shaft 11a10 drives the drive bevel gear 12a1 to rotate forward and backward, the drive bevel gear 12a1 drives the first driven bevel gear 12a2 and the second driven bevel gear 12a3 to rotate forward and backward, the rotation periods of the first driven bevel gear 12a2 and the second driven bevel gear 12a3 are respectively 90 degrees of forward rotation and 90 degrees of backward rotation, the first driven bevel gear 12a2 and the second driven bevel gear 12a3 drive the third hollow transmission shaft 12c2 and the second transmission shaft 12c1 to rotate forward and backward respectively, and the third hollow transmission shaft 12c2 and the second transmission shaft 12c1 drive the telescopic mechanism 12d to rotate.

Preferably, as shown in fig. 4 and 10, the telescopic mechanism 12d includes a telescopic fixed block 12d1, an active contact fixed round rod 12d2, a passive contact sliding round rod 12d3, a second L-shaped connecting rod 12d4, a limiting insert block 12d5, a telescopic loop rod 12d6, a cross hinge rod 12d7 and a retraction spring 12d8; the telescopic fixed block 12d1 is internally provided with a first cylindrical groove for sliding the passive contact sliding round rod 12d3, the telescopic fixed block 12d1 is internally provided with a second cylindrical groove perpendicular to the first cylindrical groove, the passive contact sliding round rod 12d3 is in contact connection with the active contact fixed round rod 12d2, one end of the active contact fixed round rod 12d2 is fixed on the shell plate 1, one side of the telescopic fixed block 12d1 is fixed with one end of a second L-shaped connecting rod 12d4, the other end of the second L-shaped connecting rod 12d4 is provided with a telescopic sleeve rod 12d6, an initial section of a fixed part of the telescopic sleeve rod 12d6 is connected with a telescopic section of a telescopic end joint of the telescopic sleeve rod 12d6 through a cross hinge rod 12d7, one side of the passive contact sliding round rod 12d3 is fixed with a limiting plug-in block 12d5 for changing the shape of the cross hinge rod 12d7, and a retracting spring 12d8 is arranged between two hinged parts corresponding to the upper and lower positions of the cross hinge rod 12d7.

In the process of rotating the telescopic mechanism 12d to the reversing position, the active contact fixed round rod 12d2 is in contact connection with the passive contact sliding round rod 12d3 to drive the passive contact sliding round rod 12d3 to move outwards, chamfering treatment is carried out on the contact end faces of the active contact fixed round rod 12d2 and the passive contact sliding round rod 12d3, the passive contact sliding round rod 12d3 drives the limiting insert block 12d5 to move, the limiting insert block 12d5 contacts and pushes the cross hinge rod 12d7, the angle between the cross rods of the cross hinge rod 12d7 is reduced, the cross hinge rod 12d7 stretches under the pushing of the limiting insert block 12d5, and the cross hinge rod 12d7 drives the telescopic section of the telescopic end joint of the telescopic sleeve rod 12d6 to move outwards of the square shell in the stretching process.

When the telescopic mechanism 12d rotates to be far away from the reversing position, the active contact fixed round rod 12d2 moves out of the second cylindrical groove, the active contact fixed round rod 12d2 does not limit the passive contact sliding round rod 12d3 any more, the retraction spring 12d8 props against the cross hinge rod 12d7 to enlarge the angle between the cross rods, the cross hinge rod 12d7 contracts, the telescopic section of the telescopic end section of the telescopic sleeve rod 12d6 is driven to move into the square shell, and the limiting insert block 12d5 and the passive contact sliding round rod 12d3 automatically reset due to the enlarged angle between the cross rods of the cross hinge rod 12d7.

Preferably, the telescopic rod 12d6 of the telescopic mechanism 12d connected to the second transmission shaft 12c1 is a 7-segment telescopic rod 12d6, and the telescopic rod 12d6 of the telescopic mechanism 12d of the third hollow transmission shaft 12c2 is a 2-segment telescopic rod 12d6.

The telescopic mechanism 12d connected with the second transmission shaft 12c1 and the telescopic mechanism 12d of the third hollow transmission shaft 12c2 are provided with telescopic loop bars 12d6 with different sections, so that 2 sampling devices 13 have different rotation radiuses, and interference when the 2 sampling devices 13 are in cross rotation during operation is avoided.

Preferably, the second bearing seat 12b1 is installed in the middle of each of the drive bevel gear 12a1, the first driven bevel gear 12a2 and the second driven bevel gear 12a3, and the second bearing seat 12b1 installed in the middle of the drive bevel gear 12a1 is connected with the other two second bearing seats 12b1 through a first L-shaped connecting rod 12b2.

Preferably, the surface of the shell plate 1 is provided with a sliding cover plate 5 for blocking the first open groove 8.

The device is used for avoiding the automatic control sampling equipment from entering sundries in the moving process and prolonging the maintenance period of the device in the square shell.

Preferably, a first of said shells 1 is surface mounted with a USB connector 4.

The USB connector 4 is used to facilitate the transfer of data from the display controller 3.

Preferably, a first of said shells 1 is surface mounted with a switch button 6.

The switch button 6 is used for controlling the automatic control sampling equipment to be switched off and on.

Preferably, the first shell plate 1 is provided with a scram reset button 7 on the surface.

The emergency stop reset button 7 is for use when the device fails or an emergency stop is required.

Preferably, as shown in fig. 11 and 12, the sampling device 13 includes a sampling machine 13a1, a shell material positioning block 13a2, a pressure sensor, a camera 13a3, a light bead 13a4 and a cotton swab slot 13a5; the end part of the sampling machine 13a1 is provided with a shell material positioning block 13a2 for installing a disposable protective shell material 15, a cotton swab slot 13a5 for installing an acquisition cotton swab 16, a camera 13a3 for identifying an acquisition area and a light lamp bead 13a4 for illuminating an oral cavity, and a pressure sensor for identifying the pressure of the acquisition cotton swab 16 is arranged inside the sampling machine 13a1.

After the disposable protective shell material 15 is arranged on the shell material positioning block 13a2 and the collecting cotton swab 16 is arranged in the cotton swab slot 13a5, the collected person bites the disposable protective shell material 15, the light lamp bead 13a4 illuminates the oral cavity of the collected person, the camera collects the oral cavity information of the collected person, the oral cavity information is displayed through the display controller 3, the display controller 3 judges whether the collecting condition is met, the collected person confirms to set up the collecting condition manually through the display controller 3 after the collecting condition is met, the sampling machine 13a1 controls the collecting cotton swab 16 to extend towards the oral cavity of the collected person, after the pressure sensor senses a certain pressure, the pressure sensor feeds back to the display controller 3, the display controller 3 controls the sampling machine 13a1 to stop working, and the collecting cotton swab 16 does not move forwards any more.

Preferably, an aluminum alloy frame for stabilizing the square shell structure is arranged inside the square shell.

Preferably, a display control panel and a control system are integrated in the display controller 3, and the display controller 3 is used for controlling the running speed, the acquisition mode of the sampling device and collecting the acquired video information of the acquirer.

Preferably, the collection mode controlled by the display controller 3 comprises ten people for collecting the cotton swab, five people for collecting the cotton swab and one person for collecting the cotton swab.

Example 2

In the embodiment 2, on the basis of the embodiment 1, a disinfection device 14 is additionally arranged in a square shell formed by splicing 6 shell plates 1 in the embodiment 1, and as shown in fig. 7, 8 and 9, the disinfection device 14 comprises a disinfection water tank 14a1, a first infusion hose 14a2, a second infusion tube 14a3, a delay liquid feeding device 14a4, a secondary isolation shell 14a5, a liquid spraying head 14a6 and a supporting plate 14a7; the disinfection water tank 14a1 is connected with 2 first infusion hoses 14a2,2 end parts of the first infusion hoses 14a2 are connected with a delay liquid delivery device 14a4,2 delay liquid delivery devices 14a4 are connected with a second infusion tube 14a3,2 second infusion tubes 14a3 are respectively connected with 2 isolation areas in a second-stage isolation shell 14a5, liquid spraying heads 14a6 are respectively arranged in the 2 isolation areas in the second-stage isolation shell 14a5, liquid spraying heads 14a6 in the 2 isolation areas are respectively connected with the second infusion tube 14a3 through capillary channels in the second-stage isolation shell 14a5, and the second-stage isolation shell 14a5 is connected with the shell plate 1 through a supporting plate 14a7.

Preferably, the delay liquid feeding device 14a4 includes an arc piston cylinder 14a41, an arc piston rod 14a42, an arc sleeve rod 14a43, a third connecting rod 14a44, a delay spring 14a45, a one-way liquid inlet valve 14a46 and a one-way liquid outlet valve 14a47; the circular arc piston cylinder 14a41 is connected with a circular arc piston plate in a sliding manner, one side of the circular arc piston plate is fixed with a circular arc piston rod 14a42, a circular arc sleeve rod 14a43 is sleeved outside the circular arc piston rod 14a42, a delay spring 14a45 is installed in the circular arc sleeve rod 14a43, a third connecting rod 14a44 is fixed at the end part of the circular arc sleeve rod 14a43, and a one-way liquid inlet valve 14a46 and a one-way liquid outlet valve 14a47 are installed inside the circular arc piston cylinder 14a41.

Preferably, the sterilizing device 14 further comprises an ultraviolet sterilizing lamp provided at the middle of the bottom end of the square housing, and the ultraviolet sterilizing lamp is turned on when the sampling device 13 is positioned in the secondary isolation housing 14a5.

In the process of rotating the second transmission shaft 12c1 and the third hollow transmission shaft 12c2, when the second transmission shaft 12c1 or the third hollow transmission shaft 12c2 rotates in the direction of a detected person, the third connecting rod 14a44 drives the circular arc piston piece to move towards the outside of the circular arc piston cylinder 14a41 through the circular arc sleeve rod 14a43, the delay spring 14a45 and the circular arc piston rod 14a42, disinfectant in the disinfection water tank 14a1 enters the circular arc piston cylinder 14a41 through the first infusion hose 14a2 and the one-way liquid inlet valve 14a46, and when the second transmission shaft 12c1 or the third hollow transmission shaft 12c2 rotates in the direction of the detected person, the third connecting rod 14a44 drives the circular arc sleeve rod 14a43 to rotate, the delay spring 14a45 is compressed, the compressed delay spring 14a45 drives the circular arc piston rod 14a42 and the circular arc piston piece to move towards the inside of the circular arc piston cylinder 14a41, and the disinfectant inside the circular arc piston cylinder 14a41 is extruded and sprayed out through the second infusion tube 14a3 and the inlet head 14a6, so that the disinfectant is sampled and sprayed to the detector 13 is detected.

It should be noted that the automatic control sampling device is not only limited to pharyngeal swab detection, but also can be used for detecting other parts such as nasal cavity, auditory canal and hair follicle of head by changing the shape of the disposable protective shell sleeved outside the shell positioning block.

The present application is not limited to the above-mentioned embodiments, and any changes or substitutions that can be easily understood by those skilled in the art within the technical scope of the present application are intended to be included in the scope of the present application.

Claims

1. An automatic control sampling device is characterized by comprising a shell plate (1), a test tube bar code scanner (2), a display controller (3), a first open slot (8), an ultrasonic sensor (9), a card reader (10), a reciprocating motion power device (11), a rotary telescopic device (12) and a sampling device (13); the device comprises 6 shell plates (1) which are spliced to form a square shell, wherein a test tube bar code scanner (2) and a display controller (3) are arranged on the surface of a first shell plate (1), a card reader (10) and an ultrasonic sensor (9) are arranged on the surface of a second shell plate (1) adjacent to the first shell plate (1), a reciprocating motion power device (11) is arranged in the square shell, the reciprocating motion power device (11) is connected with a rotary telescopic device (12), the rotary telescopic device (12) is connected with a sampling device (13), and a first opening groove (8) for the rotary telescopic device (12) to move is formed in each of the first shell plate (1) and the second shell plate (1);

the rotary telescopic device (12) comprises a telescopic mechanism (12 d), a drive bevel gear (12 a 1), a first driven bevel gear (12 a 2), a second driven bevel gear (12 a 3), a second transmission shaft (12 c 1) and a third hollow transmission shaft (12 c 2); the two sides of the drive bevel gear (12 a 1) are respectively hinged with a first driven bevel gear (12 a 2) and a second driven bevel gear (12 a 3), a third hollow transmission shaft (12 c 2) is arranged in the middle of the first driven bevel gear (12 a 2), a second transmission shaft (12 c 1) is arranged in the middle of the second driven bevel gear (12 a 3), the second transmission shaft (12 c 1) and the third hollow transmission shaft (12 c 2) have the same rotation axis, telescopic mechanisms (12 d) are arranged at the upper ends of the second transmission shaft (12 c 1) and the third hollow transmission shaft (12 c 2), and the included angle of the telescopic mechanisms (12 d) at the ends of the second transmission shaft (12 c 1) and the third hollow transmission shaft (12 c 2) is 90 degrees when the telescopic mechanisms are fully extended.

2. An automatic control sampling device according to claim 1, characterized in that the reciprocating power means (11) comprises a drive motor (11 a 1), an output shaft (11 a 2), a first rotary lever (11 a 3), a second rotary lever (11 a 4), a spur rack (11 a 5), a spur gear (11 a 6) and a first transmission shaft (11 a 10); the driving motor (11 a 1) is installed on one side of an output shaft (11 a 2), a first rotating rod (11 a 3) is installed on the other side of the output shaft (11 a 2), the first rotating rod (11 a 3) is rotationally connected with a second rotating rod (11 a 4), the second rotating rod (11 a 4) is rotationally connected with a straight rack (11 a 5), the straight rack (11 a 5) is meshed with a straight gear (11 a 6), and a first transmission shaft (11 a 10) is installed on one side of the straight gear (11 a 6).

3. An automatic control sampling device according to claim 2, characterized in that the reciprocating power means (11) further comprises a positioning rod (11 a 7), a first bearing (11 a 8) and a limiting plate (11 a 9); one end of the positioning rod (11 a 7) is fixedly provided with a first bearing (11 a 8), the first bearing (11 a 8) is sleeved on the first transmission shaft (11 a 10), a pair of limiting plates (11 a 9) are fixedly arranged in the middle of the positioning rod (11 a 7), and the limiting plates (11 a 9) are arranged on two sides of the straight rack (11 a 5).

4. An automatic control sampling device according to claim 1, wherein an aluminum alloy frame for stabilizing the square housing structure is provided inside the square housing.

5. The automatic control sampling device of claim 1, wherein the display controller is integrated with a display control panel and a control system, and the display controller is used for controlling the operation speed, the collection mode and the collection video information of the collector.

6. An automatic control sampling device according to claim 1, characterized in that the drive bevel gear (12 a 1), the first driven bevel gear (12 a 2) and the second driven bevel gear (12 a 3) are each provided with a second bearing seat (12 b 1) in the middle, and the second bearing seat (12 b 1) provided in the middle of the drive bevel gear (12 a 1) is connected with the remaining two second bearing seats (12 b 1) by a first L-shaped connecting rod (12 b 2).

7. An automatically controlled sampling device according to claim 1, characterized in that the surface of the housing plate (1) is provided with a sliding cover plate (5) for closing the first open slot (8).

8. An automatically controlled sampling device according to claim 1, characterized in that a first of said shells (1) is surface mounted with a USB connector (4).

9. An automatically controlled sampling device according to claim 1, characterized in that the first of said shells (1) is surface mounted with a scram reset button (7).